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#	Line 3 | Line 3 | Encoding: GBK
3
4		@ARTICLE{Torre2003,
5		author = {J. G. {de la Torre} and H. E. Sanchez and A. Ortega and J. G. Hernandez
6	<	and M. X. Fernandes and F. G. Diaz and M. C. L. Martinez},
6	>	and M. X. Fernandes and F. G. Diaz and M. C. L. Martinez},
7		title = {Calculation of the solution properties of flexible macromolecules:
8	<	methods and applications},
8	>	methods and applications},
9		journal = {European Biophysics Journal with Biophysics Letters},
10		year = {2003},
11		volume = {32},
#	Line 13 | Line 13 | Encoding: GBK
13		number = {5},
14		month = {Aug},
15		abstract = {While the prediction of hydrodynamic properties of rigid particles
16	<	is nowadays feasible using simple and efficient computer programs,
17	<	the calculation of such properties and, in general, the dynamic
18	<	behavior of flexible macromolecules has not reached a similar situation.
19	<	Although the theories are available, usually the computational work
20	<	is done using solutions specific for each problem. We intend to
21	<	develop computer programs that would greatly facilitate the task
22	<	of predicting solution behavior of flexible macromolecules. In this
23	<	paper, we first present an overview of the two approaches that are
24	<	most practical: the Monte Carlo rigid-body treatment, and the Brownian
25	<	dynamics simulation technique. The Monte Carlo procedure is based
26	<	on the calculation of properties for instantaneous conformations
27	<	of the macromolecule that are regarded as if they were instantaneously
28	<	rigid. We describe how a Monte Carlo program can be interfaced to
29	<	the programs in the HYDRO suite for rigid particles, and provide
30	<	an example of such calculation, for a hypothetical particle: a protein
31	<	with two domains connected by a flexible linker. We also describe
32	<	briefly the essentials of Brownian dynamics, and propose a general
33	<	mechanical model that includes several kinds of intramolecular interactions,
34	<	such as bending, internal rotation, excluded volume effects, etc.
35	<	We provide an example of the application of this methodology to
36	<	the dynamics of a semiflexible, wormlike DNA.},
16	>	is nowadays feasible using simple and efficient computer programs,
17	>	the calculation of such properties and, in general, the dynamic
18	>	behavior of flexible macromolecules has not reached a similar situation.
19	>	Although the theories are available, usually the computational work
20	>	is done using solutions specific for each problem. We intend to
21	>	develop computer programs that would greatly facilitate the task
22	>	of predicting solution behavior of flexible macromolecules. In this
23	>	paper, we first present an overview of the two approaches that are
24	>	most practical: the Monte Carlo rigid-body treatment, and the Brownian
25	>	dynamics simulation technique. The Monte Carlo procedure is based
26	>	on the calculation of properties for instantaneous conformations
27	>	of the macromolecule that are regarded as if they were instantaneously
28	>	rigid. We describe how a Monte Carlo program can be interfaced to
29	>	the programs in the HYDRO suite for rigid particles, and provide
30	>	an example of such calculation, for a hypothetical particle: a protein
31	>	with two domains connected by a flexible linker. We also describe
32	>	briefly the essentials of Brownian dynamics, and propose a general
33	>	mechanical model that includes several kinds of intramolecular interactions,
34	>	such as bending, internal rotation, excluded volume effects, etc.
35	>	We provide an example of the application of this methodology to
36	>	the dynamics of a semiflexible, wormlike DNA.},
37		annote = {724XK Times Cited:6 Cited References Count:64},
38		issn = {0175-7571},
39		uri = {<Go to ISI>://000185513400011},
#	Line 42 | Line 42 | Encoding: GBK
42		@ARTICLE{Alakent2005,
43		author = {B. Alakent and M. C. Camurdan and P. Doruker},
44		title = {Hierarchical structure of the energy landscape of proteins revisited
45	<	by time series analysis. II. Investigation of explicit solvent effects},
45	>	by time series analysis. II. Investigation of explicit solvent effects},
46		journal = {Journal of Chemical Physics},
47		year = {2005},
48		volume = {123},
#	Line 50 | Line 50 | Encoding: GBK
50		number = {14},
51		month = {Oct 8},
52		abstract = {Time series analysis tools are employed on the principal modes obtained
53	<	from the C-alpha trajectories from two independent molecular-dynamics
54	<	simulations of alpha-amylase inhibitor (tendamistat). Fluctuations
55	<	inside an energy minimum (intraminimum motions), transitions between
56	<	minima (interminimum motions), and relaxations in different hierarchical
57	<	energy levels are investigated and compared with those encountered
58	<	in vacuum by using different sampling window sizes and intervals.
59	<	The low-frequency low-indexed mode relationship, established in
60	<	vacuum, is also encountered in water, which shows the reliability
61	<	of the important dynamics information offered by principal components
62	<	analysis in water. It has been shown that examining a short data
63	<	collection period (100 ps) may result in a high population of overdamped
64	<	modes, while some of the low-frequency oscillations (< 10 cm(-1))
65	<	can be captured in water by using a longer data collection period
66	<	(1200 ps). Simultaneous analysis of short and long sampling window
67	<	sizes gives the following picture of the effect of water on protein
68	<	dynamics. Water makes the protein lose its memory: future conformations
69	<	are less dependent on previous conformations due to the lowering
70	<	of energy barriers in hierarchical levels of the energy landscape.
71	<	In short-time dynamics (< 10 ps), damping factors extracted from
72	<	time series model parameters are lowered. For tendamistat, the friction
73	<	coefficient in the Langevin equation is found to be around 40-60
74	<	cm(-1) for the low-indexed modes, compatible with literature. The
75	<	fact that water has increased the friction and that on the other
76	<	hand has lubrication effect at first sight contradicts. However,
77	<	this comes about because water enhances the transitions between
78	<	minima and forces the protein to reduce its already inherent inability
79	<	to maintain oscillations observed in vacuum. Some of the frequencies
80	<	lower than 10 cm(-1) are found to be overdamped, while those higher
81	<	than 20 cm(-1) are slightly increased. As for the long-time dynamics
82	<	in water, it is found that random-walk motion is maintained for
83	<	approximately 200 ps (about five times of that in vacuum) in the
84	<	low-indexed modes, showing the lowering of energy barriers between
85	<	the higher-level minima.},
53	>	from the C-alpha trajectories from two independent molecular-dynamics
54	>	simulations of alpha-amylase inhibitor (tendamistat). Fluctuations
55	>	inside an energy minimum (intraminimum motions), transitions between
56	>	minima (interminimum motions), and relaxations in different hierarchical
57	>	energy levels are investigated and compared with those encountered
58	>	in vacuum by using different sampling window sizes and intervals.
59	>	The low-frequency low-indexed mode relationship, established in
60	>	vacuum, is also encountered in water, which shows the reliability
61	>	of the important dynamics information offered by principal components
62	>	analysis in water. It has been shown that examining a short data
63	>	collection period (100 ps) may result in a high population of overdamped
64	>	modes, while some of the low-frequency oscillations (< 10 cm(-1))
65	>	can be captured in water by using a longer data collection period
66	>	(1200 ps). Simultaneous analysis of short and long sampling window
67	>	sizes gives the following picture of the effect of water on protein
68	>	dynamics. Water makes the protein lose its memory: future conformations
69	>	are less dependent on previous conformations due to the lowering
70	>	of energy barriers in hierarchical levels of the energy landscape.
71	>	In short-time dynamics (< 10 ps), damping factors extracted from
72	>	time series model parameters are lowered. For tendamistat, the friction
73	>	coefficient in the Langevin equation is found to be around 40-60
74	>	cm(-1) for the low-indexed modes, compatible with literature. The
75	>	fact that water has increased the friction and that on the other
76	>	hand has lubrication effect at first sight contradicts. However,
77	>	this comes about because water enhances the transitions between
78	>	minima and forces the protein to reduce its already inherent inability
79	>	to maintain oscillations observed in vacuum. Some of the frequencies
80	>	lower than 10 cm(-1) are found to be overdamped, while those higher
81	>	than 20 cm(-1) are slightly increased. As for the long-time dynamics
82	>	in water, it is found that random-walk motion is maintained for
83	>	approximately 200 ps (about five times of that in vacuum) in the
84	>	low-indexed modes, showing the lowering of energy barriers between
85	>	the higher-level minima.},
86		annote = {973OH Times Cited:1 Cited References Count:33},
87		issn = {0021-9606},
88		uri = {<Go to ISI>://000232532000064},
#	Line 99 | Line 99 | Encoding: GBK
99		@ARTICLE{Allison1991,
100		author = {S. A. Allison},
101		title = {A Brownian Dynamics Algorithm for Arbitrary Rigid Bodies - Application
102	<	to Polarized Dynamic Light-Scattering},
102	>	to Polarized Dynamic Light-Scattering},
103		journal = {Macromolecules},
104		year = {1991},
105		volume = {24},
#	Line 107 | Line 107 | Encoding: GBK
107		number = {2},
108		month = {Jan 21},
109		abstract = {A Brownian dynamics algorithm is developed to simulate dynamics experiments
110	<	of rigid macromolecules. It is applied to polarized dynamic light
111	<	scattering from rodlike sturctures and from a model of a DNA fragment
112	<	(762 base pairs). A number of rod cases are examined in which the
113	<	translational anisotropy is increased form zero to a large value.
114	<	Simulated first cumulants as well as amplitudes and lifetimes of
115	<	the dynamic form factor are compared with predictions of analytic
116	<	theories and found to be in very good agreement with them. For DNA
117	<	fragments 762 base pairs in length or longer, translational anisotropy
118	<	does not contribute significantly to dynamic light scattering. In
119	<	a comparison of rigid and flexible simulations on semistiff models
120	<	of this fragment, it is shown directly that flexing contributes
121	<	to the faster decay processes probed by light scattering and that
122	<	the flexible model studies are in good agreement with experiment.},
110	>	of rigid macromolecules. It is applied to polarized dynamic light
111	>	scattering from rodlike sturctures and from a model of a DNA fragment
112	>	(762 base pairs). A number of rod cases are examined in which the
113	>	translational anisotropy is increased form zero to a large value.
114	>	Simulated first cumulants as well as amplitudes and lifetimes of
115	>	the dynamic form factor are compared with predictions of analytic
116	>	theories and found to be in very good agreement with them. For DNA
117	>	fragments 762 base pairs in length or longer, translational anisotropy
118	>	does not contribute significantly to dynamic light scattering. In
119	>	a comparison of rigid and flexible simulations on semistiff models
120	>	of this fragment, it is shown directly that flexing contributes
121	>	to the faster decay processes probed by light scattering and that
122	>	the flexible model studies are in good agreement with experiment.},
123		annote = {Eu814 Times Cited:8 Cited References Count:32},
124		issn = {0024-9297},
125		uri = {<Go to ISI>://A1991EU81400029},
126		}
127
128	+	@ARTICLE{Andersen1983,
129	+	author = {H. C. Andersen},
130	+	title = {Rattle - a Velocity Version of the Shake Algorithm for Molecular-Dynamics
131	+	Calculations},
132	+	journal = {Journal of Computational Physics},
133	+	year = {1983},
134	+	volume = {52},
135	+	pages = {24-34},
136	+	number = {1},
137	+	annote = {Rq238 Times Cited:559 Cited References Count:14},
138	+	issn = {0021-9991},
139	+	uri = {<Go to ISI>://A1983RQ23800002},
140	+	}
141	+
142		@ARTICLE{Auerbach2005,
143		author = {A. Auerbach},
144		title = {Gating of acetylcholine receptor channels: Brownian motion across
145	<	a broad transition state},
145	>	a broad transition state},
146		journal = {Proceedings of the National Academy of Sciences of the United States
147	<	of America},
147	>	of America},
148		year = {2005},
149		volume = {102},
150		pages = {1408-1412},
151		number = {5},
152		month = {Feb 1},
153		abstract = {Acetylcholine receptor channels (AChRs) are proteins that switch between
154	<	stable #closed# and #open# conformations. In patch clamp recordings,
155	<	diliganded AChR gating appears to be a simple, two-state reaction.
156	<	However, mutagenesis studies indicate that during gating dozens
157	<	of residues across the protein move asynchronously and are organized
158	<	into rigid body gating domains (#blocks#). Moreover, there is an
159	<	upper limit to the apparent channel opening rate constant. These
160	<	observations suggest that the gating reaction has a broad, corrugated
161	<	transition state region, with the maximum opening rate reflecting,
162	<	in part, the mean first-passage time across this ensemble. Simulations
163	<	reveal that a flat, isotropic energy profile for the transition
164	<	state can account for many of the essential features of AChR gating.
165	<	With this mechanism, concerted, local structural transitions that
166	<	occur on the broad transition state ensemble give rise to fractional
167	<	measures of reaction progress (Phi values) determined by rate-equilibrium
168	<	free energy relationship analysis. The results suggest that the
169	<	coarse-grained AChR gating conformational change propagates through
170	<	the protein with dynamics that are governed by the Brownian motion
171	<	of individual gating blocks.},
154	>	stable #closed# and #open# conformations. In patch clamp recordings,
155	>	diliganded AChR gating appears to be a simple, two-state reaction.
156	>	However, mutagenesis studies indicate that during gating dozens
157	>	of residues across the protein move asynchronously and are organized
158	>	into rigid body gating domains (#blocks#). Moreover, there is an
159	>	upper limit to the apparent channel opening rate constant. These
160	>	observations suggest that the gating reaction has a broad, corrugated
161	>	transition state region, with the maximum opening rate reflecting,
162	>	in part, the mean first-passage time across this ensemble. Simulations
163	>	reveal that a flat, isotropic energy profile for the transition
164	>	state can account for many of the essential features of AChR gating.
165	>	With this mechanism, concerted, local structural transitions that
166	>	occur on the broad transition state ensemble give rise to fractional
167	>	measures of reaction progress (Phi values) determined by rate-equilibrium
168	>	free energy relationship analysis. The results suggest that the
169	>	coarse-grained AChR gating conformational change propagates through
170	>	the protein with dynamics that are governed by the Brownian motion
171	>	of individual gating blocks.},
172		annote = {895QF Times Cited:9 Cited References Count:33},
173		issn = {0027-8424},
174		uri = {<Go to ISI>://000226877300030},
#	Line 163 | Line 177 | Encoding: GBK
177		@ARTICLE{Baber1995,
178		author = {J. Baber and J. F. Ellena and D. S. Cafiso},
179		title = {Distribution of General-Anesthetics in Phospholipid-Bilayers Determined
180	<	Using H-2 Nmr and H-1-H-1 Noe Spectroscopy},
180	>	Using H-2 Nmr and H-1-H-1 Noe Spectroscopy},
181		journal = {Biochemistry},
182		year = {1995},
183		volume = {34},
#	Line 171 | Line 185 | Encoding: GBK
185		number = {19},
186		month = {May 16},
187		abstract = {The effect of the general anesthetics halothane, enflurane, and isoflurane
188	<	on hydrocarbon chain packing in palmitoyl(d(31))oleoylphosphatidylcholine
189	<	membranes in the liquid crystalline phase was investigated using
190	<	H-2 NMR. Upon the addition of the anesthetics, the first five methylene
191	<	units near the interface generally show a very small increase in
192	<	segmental order, while segments deeper within the bilayer show a
193	<	small decrease in segmental order. From the H-2 NMR results, the
194	<	chain length for the perdeuterated palmitoyl chain in the absence
195	<	of anesthetic was found to be 12.35 Angstrom. Upon the addition
196	<	of halothane enflurane, or isoflurane, the acyl chain undergoes
197	<	slight contractions of 0.11, 0.20, or 0.16 Angstrom, respectively,
198	<	at 50 mol % anesthetic. A simple model was used to estimate the
199	<	relative amounts of anesthetic located near the interface and deeper
200	<	in the bilayer hydrocarbon region, and only a slight preference
201	<	for an interfacial location was observed. Intermolecular H-1-H-1
202	<	nuclear Overhauser effects (NOEs) were measured between phospholipid
203	<	and halothane protons. These NOEs are consistent with the intramembrane
204	<	location of the anesthetics suggested by the H-2 NMR data. In addition,
205	<	the NOE data indicate that anesthetics prefer the interfacial and
206	<	hydrocarbon regions of the membrane and are not found in high concentrations
207	<	in the phospholipid headgroup.},
188	>	on hydrocarbon chain packing in palmitoyl(d(31))oleoylphosphatidylcholine
189	>	membranes in the liquid crystalline phase was investigated using
190	>	H-2 NMR. Upon the addition of the anesthetics, the first five methylene
191	>	units near the interface generally show a very small increase in
192	>	segmental order, while segments deeper within the bilayer show a
193	>	small decrease in segmental order. From the H-2 NMR results, the
194	>	chain length for the perdeuterated palmitoyl chain in the absence
195	>	of anesthetic was found to be 12.35 Angstrom. Upon the addition
196	>	of halothane enflurane, or isoflurane, the acyl chain undergoes
197	>	slight contractions of 0.11, 0.20, or 0.16 Angstrom, respectively,
198	>	at 50 mol % anesthetic. A simple model was used to estimate the
199	>	relative amounts of anesthetic located near the interface and deeper
200	>	in the bilayer hydrocarbon region, and only a slight preference
201	>	for an interfacial location was observed. Intermolecular H-1-H-1
202	>	nuclear Overhauser effects (NOEs) were measured between phospholipid
203	>	and halothane protons. These NOEs are consistent with the intramembrane
204	>	location of the anesthetics suggested by the H-2 NMR data. In addition,
205	>	the NOE data indicate that anesthetics prefer the interfacial and
206	>	hydrocarbon regions of the membrane and are not found in high concentrations
207	>	in the phospholipid headgroup.},
208		annote = {Qz716 Times Cited:38 Cited References Count:37},
209		issn = {0006-2960},
210		uri = {<Go to ISI>://A1995QZ71600035},
#	Line 199 | Line 213 | Encoding: GBK
213		@ARTICLE{Banerjee2004,
214		author = {D. Banerjee and B. C. Bag and S. K. Banik and D. S. Ray},
215		title = {Solution of quantum Langevin equation: Approximations, theoretical
216	<	and numerical aspects},
216	>	and numerical aspects},
217		journal = {Journal of Chemical Physics},
218		year = {2004},
219		volume = {120},
#	Line 207 | Line 221 | Encoding: GBK
221		number = {19},
222		month = {May 15},
223		abstract = {Based on a coherent state representation of noise operator and an
224	<	ensemble averaging procedure using Wigner canonical thermal distribution
225	<	for harmonic oscillators, a generalized quantum Langevin equation
226	<	has been recently developed [Phys. Rev. E 65, 021109 (2002); 66,
227	<	051106 (2002)] to derive the equations of motion for probability
228	<	distribution functions in c-number phase-space. We extend the treatment
229	<	to explore several systematic approximation schemes for the solutions
230	<	of the Langevin equation for nonlinear potentials for a wide range
231	<	of noise correlation, strength and temperature down to the vacuum
232	<	limit. The method is exemplified by an analytic application to harmonic
233	<	oscillator for arbitrary memory kernel and with the help of a numerical
234	<	calculation of barrier crossing, in a cubic potential to demonstrate
235	<	the quantum Kramers' turnover and the quantum Arrhenius plot. (C)
236	<	2004 American Institute of Physics.},
224	>	ensemble averaging procedure using Wigner canonical thermal distribution
225	>	for harmonic oscillators, a generalized quantum Langevin equation
226	>	has been recently developed [Phys. Rev. E 65, 021109 (2002); 66,
227	>	051106 (2002)] to derive the equations of motion for probability
228	>	distribution functions in c-number phase-space. We extend the treatment
229	>	to explore several systematic approximation schemes for the solutions
230	>	of the Langevin equation for nonlinear potentials for a wide range
231	>	of noise correlation, strength and temperature down to the vacuum
232	>	limit. The method is exemplified by an analytic application to harmonic
233	>	oscillator for arbitrary memory kernel and with the help of a numerical
234	>	calculation of barrier crossing, in a cubic potential to demonstrate
235	>	the quantum Kramers' turnover and the quantum Arrhenius plot. (C)
236	>	2004 American Institute of Physics.},
237		annote = {816YY Times Cited:8 Cited References Count:35},
238		issn = {0021-9606},
239		uri = {<Go to ISI>://000221146400009},
240		}
241
242	+	@ARTICLE{Barojas1973,
243	+	author = {J. Barojas and D. Levesque},
244	+	title = {Simulation of Diatomic Homonuclear Liquids},
245	+	journal = {Phys. Rev. A},
246	+	year = {1973},
247	+	volume = {7},
248	+	pages = {1092-1105},
249	+	}
250	+
251		@ARTICLE{Barth1998,
252		author = {E. Barth and T. Schlick},
253		title = {Overcoming stability limitations in biomolecular dynamics. I. Combining
254	<	force splitting via extrapolation with Langevin dynamics in LN},
254	>	force splitting via extrapolation with Langevin dynamics in LN},
255		journal = {Journal of Chemical Physics},
256		year = {1998},
257		volume = {109},
#	Line 236 | Line 259 | Encoding: GBK
259		number = {5},
260		month = {Aug 1},
261		abstract = {We present an efficient new method termed LN for propagating biomolecular
262	<	dynamics according to the Langevin equation that arose fortuitously
263	<	upon analysis of the range of harmonic validity of our normal-mode
264	<	scheme LIN. LN combines force linearization with force splitting
265	<	techniques and disposes of LIN'S computationally intensive minimization
266	<	(anharmonic correction) component. Unlike the competitive multiple-timestepping
267	<	(MTS) schemes today-formulated to be symplectic and time-reversible-LN
268	<	merges the slow and fast forces via extrapolation rather than impulses;
269	<	the Langevin heat bath prevents systematic energy drifts. This combination
270	<	succeeds in achieving more significant speedups than these MTS methods
271	<	which are Limited by resonance artifacts to an outer timestep less
272	<	than some integer multiple of half the period of the fastest motion
273	<	(around 4-5 fs for biomolecules). We show that LN achieves very
274	<	good agreement with small-timestep solutions of the Langevin equation
275	<	in terms of thermodynamics (energy means and variances), geometry,
276	<	and dynamics (spectral densities) for two proteins in vacuum and
277	<	a large water system. Significantly, the frequency of updating the
278	<	slow forces extends to 48 fs or more, resulting in speedup factors
279	<	exceeding 10. The implementation of LN in any program that employs
280	<	force-splitting computations is straightforward, with only partial
281	<	second-derivative information required, as well as sparse Hessian/vector
282	<	multiplication routines. The linearization part of LN could even
283	<	be replaced by direct evaluation of the fast components. The application
284	<	of LN to biomolecular dynamics is well suited for configurational
285	<	sampling, thermodynamic, and structural questions. (C) 1998 American
286	<	Institute of Physics.},
262	>	dynamics according to the Langevin equation that arose fortuitously
263	>	upon analysis of the range of harmonic validity of our normal-mode
264	>	scheme LIN. LN combines force linearization with force splitting
265	>	techniques and disposes of LIN'S computationally intensive minimization
266	>	(anharmonic correction) component. Unlike the competitive multiple-timestepping
267	>	(MTS) schemes today-formulated to be symplectic and time-reversible-LN
268	>	merges the slow and fast forces via extrapolation rather than impulses;
269	>	the Langevin heat bath prevents systematic energy drifts. This combination
270	>	succeeds in achieving more significant speedups than these MTS methods
271	>	which are Limited by resonance artifacts to an outer timestep less
272	>	than some integer multiple of half the period of the fastest motion
273	>	(around 4-5 fs for biomolecules). We show that LN achieves very
274	>	good agreement with small-timestep solutions of the Langevin equation
275	>	in terms of thermodynamics (energy means and variances), geometry,
276	>	and dynamics (spectral densities) for two proteins in vacuum and
277	>	a large water system. Significantly, the frequency of updating the
278	>	slow forces extends to 48 fs or more, resulting in speedup factors
279	>	exceeding 10. The implementation of LN in any program that employs
280	>	force-splitting computations is straightforward, with only partial
281	>	second-derivative information required, as well as sparse Hessian/vector
282	>	multiplication routines. The linearization part of LN could even
283	>	be replaced by direct evaluation of the fast components. The application
284	>	of LN to biomolecular dynamics is well suited for configurational
285	>	sampling, thermodynamic, and structural questions. (C) 1998 American
286	>	Institute of Physics.},
287		annote = {105HH Times Cited:29 Cited References Count:49},
288		issn = {0021-9606},
289		uri = {<Go to ISI>://000075066300006},
#	Line 269 | Line 292 | Encoding: GBK
292		@ARTICLE{Batcho2001,
293		author = {P. F. Batcho and T. Schlick},
294		title = {Special stability advantages of position-Verlet over velocity-Verlet
295	<	in multiple-time step integration},
295	>	in multiple-time step integration},
296		journal = {Journal of Chemical Physics},
297		year = {2001},
298		volume = {115},
#	Line 277 | Line 300 | Encoding: GBK
300		number = {9},
301		month = {Sep 1},
302		abstract = {We present an analysis for a simple two-component harmonic oscillator
303	<	that compares the use of position-Verlet to velocity-Verlet for
304	<	multiple-time step integration. The numerical stability analysis
305	<	based on the impulse-Verlet splitting shows that position-Verlet
306	<	has enhanced stability, in terms of the largest allowable time step,
307	<	for cases where an ample separation of time scales exists. Numerical
308	<	investigations confirm the advantages of the position-Verlet scheme
309	<	when used for the fastest time scales of the system. Applications
310	<	to a biomolecule. a solvated protein, for both Newtonian and Langevin
311	<	dynamics echo these trends over large outer time-step regimes. (C)
312	<	2001 American Institute of Physics.},
303	>	that compares the use of position-Verlet to velocity-Verlet for
304	>	multiple-time step integration. The numerical stability analysis
305	>	based on the impulse-Verlet splitting shows that position-Verlet
306	>	has enhanced stability, in terms of the largest allowable time step,
307	>	for cases where an ample separation of time scales exists. Numerical
308	>	investigations confirm the advantages of the position-Verlet scheme
309	>	when used for the fastest time scales of the system. Applications
310	>	to a biomolecule. a solvated protein, for both Newtonian and Langevin
311	>	dynamics echo these trends over large outer time-step regimes. (C)
312	>	2001 American Institute of Physics.},
313		annote = {469KV Times Cited:6 Cited References Count:30},
314		issn = {0021-9606},
315		uri = {<Go to ISI>://000170813800005},
#	Line 295 | Line 318 | Encoding: GBK
318		@ARTICLE{Bates2005,
319		author = {M. A. Bates and G. R. Luckhurst},
320		title = {Biaxial nematic phases and V-shaped molecules: A Monte Carlo simulation
321	<	study},
321	>	study},
322		journal = {Physical Review E},
323		year = {2005},
324		volume = {72},
#	Line 303 | Line 326 | Encoding: GBK
326		number = {5},
327		month = {Nov},
328		abstract = {Inspired by recent claims that compounds composed of V-shaped molecules
329	<	can exhibit the elusive biaxial nematic phase, we have developed
330	<	a generic simulation model for such systems. This contains the features
331	<	of the molecule that are essential to its liquid crystal behavior,
332	<	namely the anisotropies of the two arms and the angle between them.
333	<	The behavior of the model has been investigated using Monte Carlo
334	<	simulations for a wide range of these structural parameters. This
335	<	allows us to establish the relationship between the V-shaped molecule
336	<	and its ability to form a biaxial nematic phase. Of particular importance
337	<	are the criteria of geometry and the relative anisotropy necessary
338	<	for the system to exhibit a Landau point, at which the biaxial nematic
339	<	is formed directly from the isotropic phase. The simulations have
340	<	also been used to determine the orientational order parameters for
341	<	a selection of molecular axes. These are especially important because
342	<	they reveal the phase symmetry and are connected to the experimental
343	<	determination of this. The simulation results show that, whereas
344	<	some positions are extremely sensitive to the phase biaxiality,
345	<	others are totally blind to this.},
329	>	can exhibit the elusive biaxial nematic phase, we have developed
330	>	a generic simulation model for such systems. This contains the features
331	>	of the molecule that are essential to its liquid crystal behavior,
332	>	namely the anisotropies of the two arms and the angle between them.
333	>	The behavior of the model has been investigated using Monte Carlo
334	>	simulations for a wide range of these structural parameters. This
335	>	allows us to establish the relationship between the V-shaped molecule
336	>	and its ability to form a biaxial nematic phase. Of particular importance
337	>	are the criteria of geometry and the relative anisotropy necessary
338	>	for the system to exhibit a Landau point, at which the biaxial nematic
339	>	is formed directly from the isotropic phase. The simulations have
340	>	also been used to determine the orientational order parameters for
341	>	a selection of molecular axes. These are especially important because
342	>	they reveal the phase symmetry and are connected to the experimental
343	>	determination of this. The simulation results show that, whereas
344	>	some positions are extremely sensitive to the phase biaxiality,
345	>	others are totally blind to this.},
346		annote = {Part 1 988LQ Times Cited:0 Cited References Count:38},
347		issn = {1539-3755},
348		uri = {<Go to ISI>://000233603100030},
#	Line 335 | Line 358 | Encoding: GBK
358		number = {5},
359		month = {Nov 1},
360		abstract = {We introduce an unbiased protocol for performing rotational moves
361	<	in rigid-body dynamics simulations. This approach - based on the
362	<	analytic solution for the rotational equations of motion for an
363	<	orthogonal coordinate system at constant angular velocity - removes
364	<	deficiencies that have been largely ignored in Brownian dynamics
365	<	simulations, namely errors for finite rotations that result from
366	<	applying the noncommuting rotational matrices in an arbitrary order.
367	<	Our algorithm should thus replace standard approaches to rotate
368	<	local coordinate frames in Langevin and Brownian dynamics simulations.},
361	>	in rigid-body dynamics simulations. This approach - based on the
362	>	analytic solution for the rotational equations of motion for an
363	>	orthogonal coordinate system at constant angular velocity - removes
364	>	deficiencies that have been largely ignored in Brownian dynamics
365	>	simulations, namely errors for finite rotations that result from
366	>	applying the noncommuting rotational matrices in an arbitrary order.
367	>	Our algorithm should thus replace standard approaches to rotate
368	>	local coordinate frames in Langevin and Brownian dynamics simulations.},
369		annote = {736UA Times Cited:0 Cited References Count:11},
370		issn = {0006-3495},
371		uri = {<Go to ISI>://000186190500018},
#	Line 351 | Line 374 | Encoding: GBK
374		@ARTICLE{Beloborodov1998,
375		author = {I. S. Beloborodov and V. Y. Orekhov and A. S. Arseniev},
376		title = {Effect of coupling between rotational and translational Brownian
377	<	motions on NMR spin relaxation: Consideration using green function
378	<	of rigid body diffusion},
377	>	motions on NMR spin relaxation: Consideration using green function
378	>	of rigid body diffusion},
379		journal = {Journal of Magnetic Resonance},
380		year = {1998},
381		volume = {132},
#	Line 360 | Line 383 | Encoding: GBK
383		number = {2},
384		month = {Jun},
385		abstract = {Using the Green function of arbitrary rigid Brownian diffusion (Goldstein,
386	<	Biopolymers 33, 409-436, 1993), it was analytically shown that coupling
387	<	between translation and rotation diffusion degrees of freedom does
388	<	not affect the correlation functions relevant to the NMR intramolecular
389	<	relaxation. It follows that spectral densities usually used for
390	<	the anisotropic rotation diffusion (Woessner, J. Chem. Phys. 37,
391	<	647-654, 1962) can be regarded as exact in respect to the rotation-translation
392	<	coupling for the spin system connected with a rigid body. (C) 1998
393	<	Academic Press.},
386	>	Biopolymers 33, 409-436, 1993), it was analytically shown that coupling
387	>	between translation and rotation diffusion degrees of freedom does
388	>	not affect the correlation functions relevant to the NMR intramolecular
389	>	relaxation. It follows that spectral densities usually used for
390	>	the anisotropic rotation diffusion (Woessner, J. Chem. Phys. 37,
391	>	647-654, 1962) can be regarded as exact in respect to the rotation-translation
392	>	coupling for the spin system connected with a rigid body. (C) 1998
393	>	Academic Press.},
394		annote = {Zu605 Times Cited:2 Cited References Count:6},
395		issn = {1090-7807},
396		uri = {<Go to ISI>://000074214800017},
#	Line 376 | Line 399 | Encoding: GBK
399		@ARTICLE{Berardi1996,
400		author = {R. Berardi and S. Orlandi and C. Zannoni},
401		title = {Antiphase structures in polar smectic liquid crystals and their molecular
402	<	origin},
402	>	origin},
403		journal = {Chemical Physics Letters},
404		year = {1996},
405		volume = {261},
#	Line 384 | Line 407 | Encoding: GBK
407		number = {3},
408		month = {Oct 18},
409		abstract = {We demonstrate that the overall molecular dipole organization in a
410	<	smectic liquid crystal formed of polar molecules can be strongly
411	<	influenced by the position of the dipole in the molecule. We study
412	<	by large scale Monte Carlo simulations systems of attractive-repulsive
413	<	''Gay-Berne'' elongated ellipsoids with an axial dipole at the center
414	<	or near the end of the molecule and we show that monolayer smectic
415	<	liquid crystals and modulated antiferroelectric bilayer stripe domains
416	<	similar to the experimentally observed ''antiphase'' structures
417	<	are obtained in the two cases.},
410	>	smectic liquid crystal formed of polar molecules can be strongly
411	>	influenced by the position of the dipole in the molecule. We study
412	>	by large scale Monte Carlo simulations systems of attractive-repulsive
413	>	''Gay-Berne'' elongated ellipsoids with an axial dipole at the center
414	>	or near the end of the molecule and we show that monolayer smectic
415	>	liquid crystals and modulated antiferroelectric bilayer stripe domains
416	>	similar to the experimentally observed ''antiphase'' structures
417	>	are obtained in the two cases.},
418		annote = {Vn637 Times Cited:49 Cited References Count:26},
419		issn = {0009-2614},
420		uri = {<Go to ISI>://A1996VN63700023},
#	Line 399 | Line 422 | Encoding: GBK
422
423		@ARTICLE{Berkov2005,
424		author = {D. V. Berkov and N. L. Gorn},
402	–	title = {Stochastic dynamic simulations of fast remagnetization processes:
403	–	recent advances and applications},
404	–	journal = {Journal of Magnetism and Magnetic Materials},
405	–	year = {2005},
406	–	volume = {290},
407	–	pages = {442-448},
408	–	month = {Apr},
409	–	abstract = {Numerical simulations of fast remagnetization processes using stochastic
410	–	dynamics are widely used to study various magnetic systems. In this
411	–	paper, we first address several crucial methodological problems
412	–	of such simulations: (i) the influence of finite-element discretization
413	–	on simulated dynamics, (ii) choice between Ito and Stratonovich
414	–	stochastic calculi by the solution of micromagnetic stochastic equations
415	–	of motion and (iii) non-trivial correlation properties of the random
416	–	(thermal) field. Next, we discuss several examples to demonstrate
417	–	the great potential of the Langevin dynamics for studying fast remagnetization
418	–	processes in technically relevant applications: we present numerical
419	–	analysis of equilibrium magnon spectra in patterned structures,
420	–	study thermal noise effects on the magnetization dynamics of nanoelements
421	–	in pulsed fields and show some results for a remagnetization dynamics
422	–	induced by a spin-polarized current. (c) 2004 Elsevier B.V. All
423	–	rights reserved.},
424	–	annote = {Part 1 Sp. Iss. SI 922KU Times Cited:2 Cited References Count:25},
425	–	issn = {0304-8853},
426	–	uri = {<Go to ISI>://000228837600109},
427	–	}
428	–
429	–	@ARTICLE{Berkov2005a,
430	–	author = {D. V. Berkov and N. L. Gorn},
425		title = {Magnetization precession due to a spin-polarized current in a thin
426	<	nanoelement: Numerical simulation study},
426	>	nanoelement: Numerical simulation study},
427		journal = {Physical Review B},
428		year = {2005},
429		volume = {72},
#	Line 437 | Line 431 | Encoding: GBK
431		number = {9},
432		month = {Sep},
433		abstract = {In this paper a detailed numerical study (in frames of the Slonczewski
434	<	formalism) of magnetization oscillations driven by a spin-polarized
435	<	current through a thin elliptical nanoelement is presented. We show
436	<	that a sophisticated micromagnetic model, where a polycrystalline
437	<	structure of a nanoelement is taken into account, can explain qualitatively
438	<	all most important features of the magnetization oscillation spectra
439	<	recently observed experimentally [S. I. Kiselev , Nature 425, 380
440	<	(2003)], namely, existence of several equidistant spectral bands,
441	<	sharp onset and abrupt disappearance of magnetization oscillations
442	<	with increasing current, absence of the out-of-plane regime predicted
443	<	by a macrospin model, and the relation between frequencies of so-called
444	<	small-angle and quasichaotic oscillations. However, a quantitative
445	<	agreement with experimental results (especially concerning the frequency
446	<	of quasichaotic oscillations) could not be achieved in the region
447	<	of reasonable parameter values, indicating that further model refinement
448	<	is necessary for a complete understanding of the spin-driven magnetization
449	<	precession even in this relatively simple experimental situation.},
434	>	formalism) of magnetization oscillations driven by a spin-polarized
435	>	current through a thin elliptical nanoelement is presented. We show
436	>	that a sophisticated micromagnetic model, where a polycrystalline
437	>	structure of a nanoelement is taken into account, can explain qualitatively
438	>	all most important features of the magnetization oscillation spectra
439	>	recently observed experimentally [S. I. Kiselev , Nature 425, 380
440	>	(2003)], namely, existence of several equidistant spectral bands,
441	>	sharp onset and abrupt disappearance of magnetization oscillations
442	>	with increasing current, absence of the out-of-plane regime predicted
443	>	by a macrospin model, and the relation between frequencies of so-called
444	>	small-angle and quasichaotic oscillations. However, a quantitative
445	>	agreement with experimental results (especially concerning the frequency
446	>	of quasichaotic oscillations) could not be achieved in the region
447	>	of reasonable parameter values, indicating that further model refinement
448	>	is necessary for a complete understanding of the spin-driven magnetization
449	>	precession even in this relatively simple experimental situation.},
450		annote = {969IT Times Cited:2 Cited References Count:55},
451		issn = {1098-0121},
452		uri = {<Go to ISI>://000232228500058},
453		}
454
455	+	@ARTICLE{Berkov2005a,
456	+	author = {D. V. Berkov and N. L. Gorn},
457	+	title = {Stochastic dynamic simulations of fast remagnetization processes:
458	+	recent advances and applications},
459	+	journal = {Journal of Magnetism and Magnetic Materials},
460	+	year = {2005},
461	+	volume = {290},
462	+	pages = {442-448},
463	+	month = {Apr},
464	+	abstract = {Numerical simulations of fast remagnetization processes using stochastic
465	+	dynamics are widely used to study various magnetic systems. In this
466	+	paper, we first address several crucial methodological problems
467	+	of such simulations: (i) the influence of finite-element discretization
468	+	on simulated dynamics, (ii) choice between Ito and Stratonovich
469	+	stochastic calculi by the solution of micromagnetic stochastic equations
470	+	of motion and (iii) non-trivial correlation properties of the random
471	+	(thermal) field. Next, we discuss several examples to demonstrate
472	+	the great potential of the Langevin dynamics for studying fast remagnetization
473	+	processes in technically relevant applications: we present numerical
474	+	analysis of equilibrium magnon spectra in patterned structures,
475	+	study thermal noise effects on the magnetization dynamics of nanoelements
476	+	in pulsed fields and show some results for a remagnetization dynamics
477	+	induced by a spin-polarized current. (c) 2004 Elsevier B.V. All
478	+	rights reserved.},
479	+	annote = {Part 1 Sp. Iss. SI 922KU Times Cited:2 Cited References Count:25},
480	+	issn = {0304-8853},
481	+	uri = {<Go to ISI>://000228837600109},
482	+	}
483	+
484		@ARTICLE{Berkov2002,
485		author = {D. V. Berkov and N. L. Gorn and P. Gornert},
486		title = {Magnetization dynamics in nanoparticle systems: Numerical simulation
487	<	using Langevin dynamics},
487	>	using Langevin dynamics},
488		journal = {Physica Status Solidi a-Applied Research},
489		year = {2002},
490		volume = {189},
#	Line 469 | Line 492 | Encoding: GBK
492		number = {2},
493		month = {Feb 16},
494		abstract = {We report on recent progress achieved by the development of numerical
495	<	methods based on the stochastic (Langevin) dynamics applied to systems
496	<	of interacting magnetic nanoparticles. The method enables direct
497	<	simulations of the trajectories of magnetic moments taking into
498	<	account (i) all relevant interactions, (ii) precession dynamics,
499	<	and (iii) temperature fluctuations included via the random (thermal)
500	<	field. We present several novel results obtained using new methods
501	<	developed for the solution of the Langevin equations. In particular,
502	<	we have investigated magnetic nanodots and disordered granular systems
503	<	of single-domain magnetic particles. For the first case we have
504	<	calculated the spectrum and the spatial distribution of spin excitations.
505	<	For the second system the complex ac susceptibility chi(omega, T)
506	<	for various particle concentrations and particle anisotropies were
507	<	computed and compared with numerous experimental results.},
495	>	methods based on the stochastic (Langevin) dynamics applied to systems
496	>	of interacting magnetic nanoparticles. The method enables direct
497	>	simulations of the trajectories of magnetic moments taking into
498	>	account (i) all relevant interactions, (ii) precession dynamics,
499	>	and (iii) temperature fluctuations included via the random (thermal)
500	>	field. We present several novel results obtained using new methods
501	>	developed for the solution of the Langevin equations. In particular,
502	>	we have investigated magnetic nanodots and disordered granular systems
503	>	of single-domain magnetic particles. For the first case we have
504	>	calculated the spectrum and the spatial distribution of spin excitations.
505	>	For the second system the complex ac susceptibility chi(omega, T)
506	>	for various particle concentrations and particle anisotropies were
507	>	computed and compared with numerous experimental results.},
508		annote = {526TF Times Cited:4 Cited References Count:37},
509		issn = {0031-8965},
510		uri = {<Go to ISI>://000174145200026},
#	Line 490 | Line 513 | Encoding: GBK
513		@ARTICLE{Bernal1980,
514		author = {J.M. Bernal and J. G. {de la Torre}},
515		title = {Transport Properties and Hydrodynamic Centers of Rigid Macromolecules
516	<	with Arbitrary Shape},
516	>	with Arbitrary Shape},
517		journal = {Biopolymers},
518		year = {1980},
519		volume = {19},
#	Line 500 | Line 523 | Encoding: GBK
523		@ARTICLE{Brunger1984,
524		author = {A. Brunger and C. L. Brooks and M. Karplus},
525		title = {Stochastic Boundary-Conditions for Molecular-Dynamics Simulations
526	<	of St2 Water},
526	>	of St2 Water},
527		journal = {Chemical Physics Letters},
528		year = {1984},
529		volume = {105},
#	Line 511 | Line 534 | Encoding: GBK
534		uri = {<Go to ISI>://A1984SM17300007},
535		}
536
537	+	@ARTICLE{Budd1999,
538	+	author = {C. J. Budd and G. J. Collins and W. Z. Huang and R. D. Russell},
539	+	title = {Self-similar numerical solutions of the porous-medium equation using
540	+	moving mesh methods},
541	+	journal = {Philosophical Transactions of the Royal Society of London Series
542	+	a-Mathematical Physical and Engineering Sciences},
543	+	year = {1999},
544	+	volume = {357},
545	+	pages = {1047-1077},
546	+	number = {1754},
547	+	month = {Apr 15},
548	+	abstract = {This paper examines a synthesis of adaptive mesh methods with the
549	+	use of symmetry to study a partial differential equation. In particular,
550	+	it considers methods which admit discrete self-similar solutions,
551	+	examining the convergence of these to the true self-similar solution
552	+	as well as their stability. Special attention is given to the nonlinear
553	+	diffusion equation describing flow in a porous medium.},
554	+	annote = {199EE Times Cited:4 Cited References Count:14},
555	+	issn = {1364-503X},
556	+	uri = {<Go to ISI>://000080466800005},
557	+	}
558	+
559		@ARTICLE{Camp1999,
560		author = {P. J. Camp and M. P. Allen and A. J. Masters},
561		title = {Theory and computer simulation of bent-core molecules},
#	Line 521 | Line 566 | Encoding: GBK
566		number = {21},
567		month = {Dec 1},
568		abstract = {Fluids of hard bent-core molecules have been studied using theory
569	<	and computer simulation. The molecules are composed of two hard
570	<	spherocylinders, with length-to-breadth ratio L/D, joined by their
571	<	ends at an angle 180 degrees - gamma. For L/D = 2 and gamma = 0,10,20
572	<	degrees, the simulations show isotropic, nematic, smectic, and solid
573	<	phases. For L/D = 2 and gamma = 30 degrees, only isotropic, nematic,
574	<	and solid phases are in evidence, which suggests that there is a
575	<	nematic-smectic-solid triple point at an angle in the range 20 degrees
576	<	< gamma < 30 degrees. In all of the orientationally ordered fluid
577	<	phases the order is purely uniaxial. For gamma = 10 degrees and
578	<	20 degrees, at the studied densities, the solid is also uniaxially
579	<	ordered, whilst for gamma = 30 degrees the solid layers are biaxially
580	<	ordered. For L/D = 2 and gamma = 60 degrees and 90 degrees we find
581	<	no spontaneous orientational ordering. This is shown to be due to
582	<	the interlocking of dimer pairs which precludes alignment. We find
583	<	similar results for L/D = 9.5 and gamma = 72 degrees, where an isotropic-biaxial
584	<	nematic transition is predicted by Onsager theory. Simulations in
585	<	the biaxial nematic phase show it to be at least mechanically stable
586	<	with respect to the isotropic phase, however. We have compared the
587	<	quasi-exact simulation results in the isotropic phase with the predicted
588	<	equations of state from three theories: the virial expansion containing
589	<	the second and third virial coefficients; the Parsons-Lee equation
590	<	of state; an application of Wertheim's theory of associating fluids
591	<	in the limit of infinite attractive association energy. For all
592	<	of the molecule elongations and geometries we have simulated, the
593	<	Wertheim theory proved to be the most accurate. Interestingly, the
594	<	isotropic equation of state is virtually independent of the dimer
595	<	bond angle-a feature that is also reflected in the lack of variation
596	<	with angle of the calculated second and third virial coefficients.
597	<	(C) 1999 American Institute of Physics. [S0021-9606(99)50445-5].},
569	>	and computer simulation. The molecules are composed of two hard
570	>	spherocylinders, with length-to-breadth ratio L/D, joined by their
571	>	ends at an angle 180 degrees - gamma. For L/D = 2 and gamma = 0,10,20
572	>	degrees, the simulations show isotropic, nematic, smectic, and solid
573	>	phases. For L/D = 2 and gamma = 30 degrees, only isotropic, nematic,
574	>	and solid phases are in evidence, which suggests that there is a
575	>	nematic-smectic-solid triple point at an angle in the range 20 degrees
576	>	< gamma < 30 degrees. In all of the orientationally ordered fluid
577	>	phases the order is purely uniaxial. For gamma = 10 degrees and
578	>	20 degrees, at the studied densities, the solid is also uniaxially
579	>	ordered, whilst for gamma = 30 degrees the solid layers are biaxially
580	>	ordered. For L/D = 2 and gamma = 60 degrees and 90 degrees we find
581	>	no spontaneous orientational ordering. This is shown to be due to
582	>	the interlocking of dimer pairs which precludes alignment. We find
583	>	similar results for L/D = 9.5 and gamma = 72 degrees, where an isotropic-biaxial
584	>	nematic transition is predicted by Onsager theory. Simulations in
585	>	the biaxial nematic phase show it to be at least mechanically stable
586	>	with respect to the isotropic phase, however. We have compared the
587	>	quasi-exact simulation results in the isotropic phase with the predicted
588	>	equations of state from three theories: the virial expansion containing
589	>	the second and third virial coefficients; the Parsons-Lee equation
590	>	of state; an application of Wertheim's theory of associating fluids
591	>	in the limit of infinite attractive association energy. For all
592	>	of the molecule elongations and geometries we have simulated, the
593	>	Wertheim theory proved to be the most accurate. Interestingly, the
594	>	isotropic equation of state is virtually independent of the dimer
595	>	bond angle-a feature that is also reflected in the lack of variation
596	>	with angle of the calculated second and third virial coefficients.
597	>	(C) 1999 American Institute of Physics. [S0021-9606(99)50445-5].},
598		annote = {255TC Times Cited:24 Cited References Count:38},
599		issn = {0021-9606},
600		uri = {<Go to ISI>://000083685400056},
#	Line 565 | Line 610 | Encoding: GBK
610		number = {11},
611		month = {Nov},
612		abstract = {A review is presented of molecular and mesoscopic computer simulations
613	<	of liquid crystalline systems. Molecular simulation approaches applied
614	<	to such systems are described, and the key findings for bulk phase
615	<	behaviour are reported. Following this, recently developed lattice
616	<	Boltzmann approaches to the mesoscale modelling of nemato-dynanics
617	<	are reviewed. This paper concludes with a discussion of possible
618	<	areas for future development in this field.},
613	>	of liquid crystalline systems. Molecular simulation approaches applied
614	>	to such systems are described, and the key findings for bulk phase
615	>	behaviour are reported. Following this, recently developed lattice
616	>	Boltzmann approaches to the mesoscale modelling of nemato-dynanics
617	>	are reviewed. This paper concludes with a discussion of possible
618	>	areas for future development in this field.},
619		annote = {989TU Times Cited:2 Cited References Count:258},
620		issn = {0034-4885},
621		uri = {<Go to ISI>://000233697600004},
#	Line 579 | Line 624 | Encoding: GBK
624		@ARTICLE{Carrasco1999,
625		author = {B. Carrasco and J. G. {de la Torre}},
626		title = {Hydrodynamic properties of rigid particles: Comparison of different
627	<	modeling and computational procedures},
627	>	modeling and computational procedures},
628		journal = {Biophysical Journal},
629		year = {1999},
630		volume = {76},
#	Line 587 | Line 632 | Encoding: GBK
632		number = {6},
633		month = {Jun},
634		abstract = {The hydrodynamic properties of rigid particles are calculated from
635	<	models composed of spherical elements (beads) using theories developed
636	<	by Kirkwood, Bloomfield, and their coworkers. Bead models have usually
637	<	been built in such a way that the beads fill the volume occupied
638	<	by the particles. Sometimes the beads are few and of varying sizes
639	<	(bead models in the strict sense), and other times there are many
640	<	small beads (filling models). Because hydrodynamic friction takes
641	<	place at the molecular surface, another possibility is to use shell
642	<	models, as originally proposed by Bloomfield. In this work, we have
643	<	developed procedures to build models of the various kinds, and we
644	<	describe the theory and methods for calculating their hydrodynamic
645	<	properties, including approximate methods that may be needed to
646	<	treat models with a very large number of elements. By combining
647	<	the various possibilities of model building and hydrodynamic calculation,
648	<	several strategies can be designed. We have made a quantitative
649	<	comparison of the performance of the various strategies by applying
650	<	them to some test cases, for which the properties are known a priori.
651	<	We provide guidelines and computational tools for bead modeling.},
635	>	models composed of spherical elements (beads) using theories developed
636	>	by Kirkwood, Bloomfield, and their coworkers. Bead models have usually
637	>	been built in such a way that the beads fill the volume occupied
638	>	by the particles. Sometimes the beads are few and of varying sizes
639	>	(bead models in the strict sense), and other times there are many
640	>	small beads (filling models). Because hydrodynamic friction takes
641	>	place at the molecular surface, another possibility is to use shell
642	>	models, as originally proposed by Bloomfield. In this work, we have
643	>	developed procedures to build models of the various kinds, and we
644	>	describe the theory and methods for calculating their hydrodynamic
645	>	properties, including approximate methods that may be needed to
646	>	treat models with a very large number of elements. By combining
647	>	the various possibilities of model building and hydrodynamic calculation,
648	>	several strategies can be designed. We have made a quantitative
649	>	comparison of the performance of the various strategies by applying
650	>	them to some test cases, for which the properties are known a priori.
651	>	We provide guidelines and computational tools for bead modeling.},
652		annote = {200TT Times Cited:46 Cited References Count:57},
653		issn = {0006-3495},
654		uri = {<Go to ISI>://000080556700016},
#	Line 612 | Line 657 | Encoding: GBK
657		@ARTICLE{Chandra1999,
658		author = {A. Chandra and T. Ichiye},
659		title = {Dynamical properties of the soft sticky dipole model of water: Molecular
660	<	dynamics simulations},
660	>	dynamics simulations},
661		journal = {Journal of Chemical Physics},
662		year = {1999},
663		volume = {111},
#	Line 620 | Line 665 | Encoding: GBK
665		number = {6},
666		month = {Aug 8},
667		abstract = {Dynamical properties of the soft sticky dipole (SSD) model of water
668	<	are calculated by means of molecular dynamics simulations. Since
669	<	this is not a simple point model, the forces and torques arising
670	<	from the SSD potential are derived here. Simulations are carried
671	<	out in the microcanonical ensemble employing the Ewald method for
672	<	the electrostatic interactions. Various time correlation functions
673	<	and dynamical quantities associated with the translational and rotational
674	<	motion of water molecules are evaluated and compared with those
675	<	of two other commonly used models of liquid water, namely the transferable
676	<	intermolecular potential-three points (TIP3P) and simple point charge/extended
677	<	(SPC/E) models, and also with experiments. The dynamical properties
678	<	of the SSD water model are found to be in good agreement with the
679	<	experimental results and appear to be better than the TIP3P and
680	<	SPC/E models in most cases, as has been previously shown for its
681	<	thermodynamic, structural, and dielectric properties. Also, molecular
682	<	dynamics simulations of the SSD model are found to run much faster
683	<	than TIP3P, SPC/E, and other multisite models. (C) 1999 American
684	<	Institute of Physics. [S0021-9606(99)51430-X].},
668	>	are calculated by means of molecular dynamics simulations. Since
669	>	this is not a simple point model, the forces and torques arising
670	>	from the SSD potential are derived here. Simulations are carried
671	>	out in the microcanonical ensemble employing the Ewald method for
672	>	the electrostatic interactions. Various time correlation functions
673	>	and dynamical quantities associated with the translational and rotational
674	>	motion of water molecules are evaluated and compared with those
675	>	of two other commonly used models of liquid water, namely the transferable
676	>	intermolecular potential-three points (TIP3P) and simple point charge/extended
677	>	(SPC/E) models, and also with experiments. The dynamical properties
678	>	of the SSD water model are found to be in good agreement with the
679	>	experimental results and appear to be better than the TIP3P and
680	>	SPC/E models in most cases, as has been previously shown for its
681	>	thermodynamic, structural, and dielectric properties. Also, molecular
682	>	dynamics simulations of the SSD model are found to run much faster
683	>	than TIP3P, SPC/E, and other multisite models. (C) 1999 American
684	>	Institute of Physics. [S0021-9606(99)51430-X].},
685		annote = {221EN Times Cited:14 Cited References Count:66},
686		issn = {0021-9606},
687		uri = {<Go to ISI>://000081711200038},
688		}
689
690	+	@ARTICLE{Channell1990,
691	+	author = {P. J. Channell and C. Scovel},
692	+	title = {Symplectic Integration of Hamiltonian-Systems},
693	+	journal = {Nonlinearity},
694	+	year = {1990},
695	+	volume = {3},
696	+	pages = {231-259},
697	+	number = {2},
698	+	month = {may},
699	+	annote = {Dk631 Times Cited:152 Cited References Count:34},
700	+	issn = {0951-7715},
701	+	uri = {<Go to ISI>://A1990DK63100001},
702	+	}
703	+
704	+	@ARTICLE{Chen2003,
705	+	author = {B. Chen and F. Solis},
706	+	title = {Explicit mixed finite order Runge-Kutta methods},
707	+	journal = {Applied Numerical Mathematics},
708	+	year = {2003},
709	+	volume = {44},
710	+	pages = {21-30},
711	+	number = {1-2},
712	+	month = {Jan},
713	+	abstract = {We investigate the asymptotic behavior of systems of nonlinear differential
714	+	equations and introduce a family of mixed methods from combinations
715	+	of explicit Runge-Kutta methods. These methods have better stability
716	+	behavior than traditional Runge-Kutta methods and generally extend
717	+	the range of validity of the calculated solutions. These methods
718	+	also give a way of determining if the numerical solutions are real
719	+	or spurious. Emphasis is put on examples coming from mathematical
720	+	models in ecology. (C) 2002 IMACS. Published by Elsevier Science
721	+	B.V. All rights reserved.},
722	+	annote = {633ZD Times Cited:0 Cited References Count:9},
723	+	issn = {0168-9274},
724	+	uri = {<Go to ISI>://000180314200002},
725	+	}
726	+
727		@ARTICLE{Cheung2004,
728		author = {D. L. Cheung and S. J. Clark and M. R. Wilson},
729		title = {Calculation of flexoelectric coefficients for a nematic liquid crystal
730	<	by atomistic simulation},
730	>	by atomistic simulation},
731		journal = {Journal of Chemical Physics},
732		year = {2004},
733		volume = {121},
#	Line 653 | Line 735 | Encoding: GBK
735		number = {18},
736		month = {Nov 8},
737		abstract = {Equilibrium molecular dynamics calculations have been performed for
738	<	the liquid crystal molecule n-4-(trans-4-n-pentylcyclohexyl)benzonitrile
739	<	(PCH5) using a fully atomistic model. Simulation data have been
740	<	obtained for a series of temperatures in the nematic phase. The
741	<	simulation data have been used to calculate the flexoelectric coefficients
742	<	e(s) and e(b) using the linear response formalism of Osipov and
743	<	Nemtsov [M. A. Osipov and V. B. Nemtsov, Sov. Phys. Crstallogr.
744	<	31, 125 (1986)]. The temperature and order parameter dependence
745	<	of e(s) and e(b) are examined, as are separate contributions from
746	<	different intermolecular interactions. Values of e(s) and e(b) calculated
747	<	from simulation are consistent with those found from experiment.
748	<	(C) 2004 American Institute of Physics.},
738	>	the liquid crystal molecule n-4-(trans-4-n-pentylcyclohexyl)benzonitrile
739	>	(PCH5) using a fully atomistic model. Simulation data have been
740	>	obtained for a series of temperatures in the nematic phase. The
741	>	simulation data have been used to calculate the flexoelectric coefficients
742	>	e(s) and e(b) using the linear response formalism of Osipov and
743	>	Nemtsov [M. A. Osipov and V. B. Nemtsov, Sov. Phys. Crstallogr.
744	>	31, 125 (1986)]. The temperature and order parameter dependence
745	>	of e(s) and e(b) are examined, as are separate contributions from
746	>	different intermolecular interactions. Values of e(s) and e(b) calculated
747	>	from simulation are consistent with those found from experiment.
748	>	(C) 2004 American Institute of Physics.},
749		annote = {866UM Times Cited:4 Cited References Count:61},
750		issn = {0021-9606},
751		uri = {<Go to ISI>://000224798900053},
#	Line 679 | Line 761 | Encoding: GBK
761		number = {1-2},
762		month = {Apr 15},
763		abstract = {Equilibrium molecular dynamics calculations have been performed for
764	<	the liquid crystal molecule n-4-(trans-4-npentylcyclohexyl)benzonitrile
765	<	(PCH5) using a fully atomistic model. Simulation data has been obtained
766	<	for a series of temperatures in the nematic phase. The rotational
767	<	viscosity co-efficient gamma(1), has been calculated using the angular
768	<	velocity correlation function of the nematic director, n, the mean
769	<	squared diffusion of n and statistical mechanical methods based
770	<	on the rotational diffusion co-efficient. We find good agreement
771	<	between the first two methods and experimental values. (C) 2002
772	<	Published by Elsevier Science B.V.},
764	>	the liquid crystal molecule n-4-(trans-4-npentylcyclohexyl)benzonitrile
765	>	(PCH5) using a fully atomistic model. Simulation data has been obtained
766	>	for a series of temperatures in the nematic phase. The rotational
767	>	viscosity co-efficient gamma(1), has been calculated using the angular
768	>	velocity correlation function of the nematic director, n, the mean
769	>	squared diffusion of n and statistical mechanical methods based
770	>	on the rotational diffusion co-efficient. We find good agreement
771	>	between the first two methods and experimental values. (C) 2002
772	>	Published by Elsevier Science B.V.},
773		annote = {547KF Times Cited:8 Cited References Count:31},
774		issn = {0009-2614},
775		uri = {<Go to ISI>://000175331000020},
#	Line 696 | Line 778 | Encoding: GBK
778		@ARTICLE{Chin2004,
779		author = {S. A. Chin},
780		title = {Dynamical multiple-time stepping methods for overcoming resonance
781	<	instabilities},
781	>	instabilities},
782		journal = {Journal of Chemical Physics},
783		year = {2004},
784		volume = {120},
#	Line 704 | Line 786 | Encoding: GBK
786		number = {1},
787		month = {Jan 1},
788		abstract = {Current molecular dynamics simulations of biomolecules using multiple
789	<	time steps to update the slowly changing force are hampered by instabilities
790	<	beginning at time steps near the half period of the fastest vibrating
791	<	mode. These #resonance# instabilities have became a critical barrier
792	<	preventing the long time simulation of biomolecular dynamics. Attempts
793	<	to tame these instabilities by altering the slowly changing force
794	<	and efforts to damp them out by Langevin dynamics do not address
795	<	the fundamental cause of these instabilities. In this work, we trace
796	<	the instability to the nonanalytic character of the underlying spectrum
797	<	and show that a correct splitting of the Hamiltonian, which renders
798	<	the spectrum analytic, restores stability. The resulting Hamiltonian
799	<	dictates that in addition to updating the momentum due to the slowly
800	<	changing force, one must also update the position with a modified
801	<	mass. Thus multiple-time stepping must be done dynamically. (C)
802	<	2004 American Institute of Physics.},
789	>	time steps to update the slowly changing force are hampered by instabilities
790	>	beginning at time steps near the half period of the fastest vibrating
791	>	mode. These #resonance# instabilities have became a critical barrier
792	>	preventing the long time simulation of biomolecular dynamics. Attempts
793	>	to tame these instabilities by altering the slowly changing force
794	>	and efforts to damp them out by Langevin dynamics do not address
795	>	the fundamental cause of these instabilities. In this work, we trace
796	>	the instability to the nonanalytic character of the underlying spectrum
797	>	and show that a correct splitting of the Hamiltonian, which renders
798	>	the spectrum analytic, restores stability. The resulting Hamiltonian
799	>	dictates that in addition to updating the momentum due to the slowly
800	>	changing force, one must also update the position with a modified
801	>	mass. Thus multiple-time stepping must be done dynamically. (C)
802	>	2004 American Institute of Physics.},
803		annote = {757TK Times Cited:1 Cited References Count:22},
804		issn = {0021-9606},
805		uri = {<Go to ISI>://000187577400003},
#	Line 726 | Line 808 | Encoding: GBK
808		@ARTICLE{Cook2000,
809		author = {M. J. Cook and M. R. Wilson},
810		title = {Simulation studies of dipole correlation in the isotropic liquid
811	<	phase},
811	>	phase},
812		journal = {Liquid Crystals},
813		year = {2000},
814		volume = {27},
#	Line 734 | Line 816 | Encoding: GBK
816		number = {12},
817		month = {Dec},
818		abstract = {The Kirkwood correlation factor g(1) determines the preference for
819	<	local parallel or antiparallel dipole association in the isotropic
820	<	phase. Calamitic mesogens with longitudinal dipole moments and Kirkwood
821	<	factors greater than 1 have an enhanced effective dipole moment
822	<	along the molecular long axis. This leads to higher values of Delta
823	<	epsilon in the nematic phase. This paper describes state-of-the-art
824	<	molecular dynamics simulations of two calamitic mesogens 4-(trans-4-n-pentylcyclohexyl)benzonitrile
825	<	(PCH5) and 4-(trans-4-n-pentylcyclohexyl) chlorobenzene (PCH5-Cl)
826	<	in the isotropic liquid phase using an all-atom force field and
827	<	taking long range electrostatics into account using an Ewald summation.
828	<	Using this methodology, PCH5 is seen to prefer antiparallel dipole
829	<	alignment with a negative g(1) and PCH5-Cl is seen to prefer parallel
830	<	dipole alignment with a positive g(1); this is in accordance with
831	<	experimental dielectric measurements. Analysis of the molecular
832	<	dynamics trajectories allows an assessment of why these molecules
833	<	behave differently.},
819	>	local parallel or antiparallel dipole association in the isotropic
820	>	phase. Calamitic mesogens with longitudinal dipole moments and Kirkwood
821	>	factors greater than 1 have an enhanced effective dipole moment
822	>	along the molecular long axis. This leads to higher values of Delta
823	>	epsilon in the nematic phase. This paper describes state-of-the-art
824	>	molecular dynamics simulations of two calamitic mesogens 4-(trans-4-n-pentylcyclohexyl)benzonitrile
825	>	(PCH5) and 4-(trans-4-n-pentylcyclohexyl) chlorobenzene (PCH5-Cl)
826	>	in the isotropic liquid phase using an all-atom force field and
827	>	taking long range electrostatics into account using an Ewald summation.
828	>	Using this methodology, PCH5 is seen to prefer antiparallel dipole
829	>	alignment with a negative g(1) and PCH5-Cl is seen to prefer parallel
830	>	dipole alignment with a positive g(1); this is in accordance with
831	>	experimental dielectric measurements. Analysis of the molecular
832	>	dynamics trajectories allows an assessment of why these molecules
833	>	behave differently.},
834		annote = {376BF Times Cited:10 Cited References Count:16},
835		issn = {0267-8292},
836		uri = {<Go to ISI>://000165437800002},
#	Line 757 | Line 839 | Encoding: GBK
839		@ARTICLE{Cui2003,
840		author = {B. X. Cui and M. Y. Shen and K. F. Freed},
841		title = {Folding and misfolding of the papillomavirus E6 interacting peptide
842	<	E6ap},
842	>	E6ap},
843		journal = {Proceedings of the National Academy of Sciences of the United States
844	<	of America},
844	>	of America},
845		year = {2003},
846		volume = {100},
847		pages = {7087-7092},
848		number = {12},
849		month = {Jun 10},
850		abstract = {All-atom Langevin dynamics simulations have been performed to study
851	<	the folding pathways of the 18-residue binding domain fragment E6ap
852	<	of the human papillomavirus E6 interacting peptide. Six independent
853	<	folding trajectories, with a total duration of nearly 2 mus, all
854	<	lead to the same native state in which the E6ap adopts a fluctuating
855	<	a-helix structure in the central portion (Ser-4-Leu-13) but with
856	<	very flexible N and C termini. Simulations starting from different
857	<	core configurations exhibit the E6ap folding dynamics as either
858	<	a two- or three-state folder with an intermediate misfolded state.
859	<	The essential leucine hydrophobic core (Leu-9, Leu-12, and Leu-13)
860	<	is well conserved in the native-state structure but absent in the
861	<	intermediate structure, suggesting that the leucine core is not
862	<	only essential for the binding activity of E6ap but also important
863	<	for the stability of the native structure. The free energy landscape
864	<	reveals a significant barrier between the basins separating the
865	<	native and misfolded states. We also discuss the various underlying
866	<	forces that drive the peptide into its native state.},
851	>	the folding pathways of the 18-residue binding domain fragment E6ap
852	>	of the human papillomavirus E6 interacting peptide. Six independent
853	>	folding trajectories, with a total duration of nearly 2 mus, all
854	>	lead to the same native state in which the E6ap adopts a fluctuating
855	>	a-helix structure in the central portion (Ser-4-Leu-13) but with
856	>	very flexible N and C termini. Simulations starting from different
857	>	core configurations exhibit the E6ap folding dynamics as either
858	>	a two- or three-state folder with an intermediate misfolded state.
859	>	The essential leucine hydrophobic core (Leu-9, Leu-12, and Leu-13)
860	>	is well conserved in the native-state structure but absent in the
861	>	intermediate structure, suggesting that the leucine core is not
862	>	only essential for the binding activity of E6ap but also important
863	>	for the stability of the native structure. The free energy landscape
864	>	reveals a significant barrier between the basins separating the
865	>	native and misfolded states. We also discuss the various underlying
866	>	forces that drive the peptide into its native state.},
867		annote = {689LC Times Cited:3 Cited References Count:48},
868		issn = {0027-8424},
869		uri = {<Go to ISI>://000183493500037},
#	Line 797 | Line 879 | Encoding: GBK
879		number = {1},
880		month = {Jan 1},
881		abstract = {We study the slow phase of thermally activated magnetic relaxation
882	<	in finite two-dimensional ensembles of dipolar interacting ferromagnetic
883	<	nanoparticles whose easy axes of magnetization are perpendicular
884	<	to the distribution plane. We develop a method to numerically simulate
885	<	the magnetic relaxation for the case that the smallest heights of
886	<	the potential barriers between the equilibrium directions of the
887	<	nanoparticle magnetic moments are much larger than the thermal energy.
888	<	Within this framework, we analyze in detail the role that the correlations
889	<	of the nanoparticle magnetic moments and the finite size of the
890	<	nanoparticle ensemble play in magnetic relaxation.},
882	>	in finite two-dimensional ensembles of dipolar interacting ferromagnetic
883	>	nanoparticles whose easy axes of magnetization are perpendicular
884	>	to the distribution plane. We develop a method to numerically simulate
885	>	the magnetic relaxation for the case that the smallest heights of
886	>	the potential barriers between the equilibrium directions of the
887	>	nanoparticle magnetic moments are much larger than the thermal energy.
888	>	Within this framework, we analyze in detail the role that the correlations
889	>	of the nanoparticle magnetic moments and the finite size of the
890	>	nanoparticle ensemble play in magnetic relaxation.},
891		annote = {642XH Times Cited:11 Cited References Count:31},
892		issn = {1098-0121},
893		uri = {<Go to ISI>://000180830400056},
#	Line 821 | Line 903 | Encoding: GBK
903		number = {1},
904		month = {Jan},
905		abstract = {To explore the origin of the large-scale motion of triosephosphate
906	<	isomerase's flexible loop (residues 166 to 176) at the active site,
907	<	several simulation protocols are employed both for the free enzyme
908	<	in vacuo and for the free enzyme with some solvent modeling: high-temperature
909	<	Langevin dynamics simulations, sampling by a #dynamics##driver#
910	<	approach, and potential-energy surface calculations. Our focus is
911	<	on obtaining the energy barrier to the enzyme's motion and establishing
912	<	the nature of the loop movement. Previous calculations did not determine
913	<	this energy barrier and the effect of solvent on the barrier. High-temperature
914	<	molecular dynamics simulations and crystallographic studies have
915	<	suggested a rigid-body motion with two hinges located at both ends
916	<	of the loop; Brownian dynamics simulations at room temperature pointed
917	<	to a very flexible behavior. The present simulations and analyses
918	<	reveal that although solute/solvent hydrogen bonds play a crucial
919	<	role in lowering the energy along the pathway, there still remains
920	<	a high activation barrier, This finding clearly indicates that,
921	<	if the loop opens and closes in the absence of a substrate at standard
922	<	conditions (e.g., room temperature, appropriate concentration of
923	<	isomerase), the time scale for transition is not in the nanosecond
924	<	but rather the microsecond range. Our results also indicate that
925	<	in the context of spontaneous opening in the free enzyme, the motion
926	<	is of rigid-body type and that the specific interaction between
927	<	residues Ala(176) and Tyr(208) plays a crucial role in the loop
928	<	opening/closing mechanism.},
906	>	isomerase's flexible loop (residues 166 to 176) at the active site,
907	>	several simulation protocols are employed both for the free enzyme
908	>	in vacuo and for the free enzyme with some solvent modeling: high-temperature
909	>	Langevin dynamics simulations, sampling by a #dynamics##driver#
910	>	approach, and potential-energy surface calculations. Our focus is
911	>	on obtaining the energy barrier to the enzyme's motion and establishing
912	>	the nature of the loop movement. Previous calculations did not determine
913	>	this energy barrier and the effect of solvent on the barrier. High-temperature
914	>	molecular dynamics simulations and crystallographic studies have
915	>	suggested a rigid-body motion with two hinges located at both ends
916	>	of the loop; Brownian dynamics simulations at room temperature pointed
917	>	to a very flexible behavior. The present simulations and analyses
918	>	reveal that although solute/solvent hydrogen bonds play a crucial
919	>	role in lowering the energy along the pathway, there still remains
920	>	a high activation barrier, This finding clearly indicates that,
921	>	if the loop opens and closes in the absence of a substrate at standard
922	>	conditions (e.g., room temperature, appropriate concentration of
923	>	isomerase), the time scale for transition is not in the nanosecond
924	>	but rather the microsecond range. Our results also indicate that
925	>	in the context of spontaneous opening in the free enzyme, the motion
926	>	is of rigid-body type and that the specific interaction between
927	>	residues Ala(176) and Tyr(208) plays a crucial role in the loop
928	>	opening/closing mechanism.},
929		annote = {Zl046 Times Cited:30 Cited References Count:29},
930		issn = {0006-3495},
931		uri = {<Go to ISI>://000073393400009},
#	Line 859 | Line 941 | Encoding: GBK
941		number = {15},
942		month = {Oct 15},
943		abstract = {Rigid body molecular models possess symplectic structure and time-reversal
944	<	symmetry. Standard numerical integration methods destroy both properties,
945	<	introducing nonphysical dynamical behavior such as numerically induced
946	<	dissipative states and drift in the energy during long term simulations.
947	<	This article describes the construction, implementation, and practical
948	<	application of fast explicit symplectic-reversible integrators for
949	<	multiple rigid body molecular simulations, These methods use a reduction
950	<	to Euler equations for the free rigid body, together with a symplectic
951	<	splitting technique. In every time step, the orientational dynamics
952	<	of each rigid body is integrated by a sequence of planar rotations.
953	<	Besides preserving the symplectic and reversible structures of the
954	<	flow, this scheme accurately conserves the total angular momentum
955	<	of a system of interacting rigid bodies. Excellent energy conservation
956	<	fan be obtained relative to traditional methods, especially in long-time
957	<	simulations. The method is implemented in a research code, ORIENT
958	<	and compared with a quaternion/extrapolation scheme for the TIP4P
959	<	model of water. Our experiments show that the symplectic-reversible
960	<	scheme is far superior to the more traditional quaternion method.
961	<	(C) 1997 American Institute of Physics.},
944	>	symmetry. Standard numerical integration methods destroy both properties,
945	>	introducing nonphysical dynamical behavior such as numerically induced
946	>	dissipative states and drift in the energy during long term simulations.
947	>	This article describes the construction, implementation, and practical
948	>	application of fast explicit symplectic-reversible integrators for
949	>	multiple rigid body molecular simulations, These methods use a reduction
950	>	to Euler equations for the free rigid body, together with a symplectic
951	>	splitting technique. In every time step, the orientational dynamics
952	>	of each rigid body is integrated by a sequence of planar rotations.
953	>	Besides preserving the symplectic and reversible structures of the
954	>	flow, this scheme accurately conserves the total angular momentum
955	>	of a system of interacting rigid bodies. Excellent energy conservation
956	>	fan be obtained relative to traditional methods, especially in long-time
957	>	simulations. The method is implemented in a research code, ORIENT
958	>	and compared with a quaternion/extrapolation scheme for the TIP4P
959	>	model of water. Our experiments show that the symplectic-reversible
960	>	scheme is far superior to the more traditional quaternion method.
961	>	(C) 1997 American Institute of Physics.},
962		annote = {Ya587 Times Cited:35 Cited References Count:32},
963		issn = {0021-9606},
964		uri = {<Go to ISI>://A1997YA58700024},
#	Line 885 | Line 967 | Encoding: GBK
967		@ARTICLE{Edwards2005,
968		author = {S. A. Edwards and D. R. M. Williams},
969		title = {Stretching a single diblock copolymer in a selective solvent: Langevin
970	<	dynamics simulations},
970	>	dynamics simulations},
971		journal = {Macromolecules},
972		year = {2005},
973		volume = {38},
#	Line 893 | Line 975 | Encoding: GBK
975		number = {25},
976		month = {Dec 13},
977		abstract = {Using the Langevin dynamics technique, we have carried out simulations
978	<	of a single-chain flexible diblock copolymer. The polymer consists
979	<	of two blocks of equal length, one very poorly solvated and the
980	<	other close to theta-conditions. We study what happens when such
981	<	a polymer is stretched, for a range of different stretching speeds,
982	<	and correlate our observations with features in the plot of force
983	<	vs extension. We find that at slow speeds this force profile does
984	<	not increase monotonically, in disagreement with earlier predictions,
985	<	and that at high speeds there is a strong dependence on which end
986	<	of the polymer is pulled, as well as a high level of hysteresis.},
978	>	of a single-chain flexible diblock copolymer. The polymer consists
979	>	of two blocks of equal length, one very poorly solvated and the
980	>	other close to theta-conditions. We study what happens when such
981	>	a polymer is stretched, for a range of different stretching speeds,
982	>	and correlate our observations with features in the plot of force
983	>	vs extension. We find that at slow speeds this force profile does
984	>	not increase monotonically, in disagreement with earlier predictions,
985	>	and that at high speeds there is a strong dependence on which end
986	>	of the polymer is pulled, as well as a high level of hysteresis.},
987		annote = {992EC Times Cited:0 Cited References Count:13},
988		issn = {0024-9297},
989		uri = {<Go to ISI>://000233866200035},
#	Line 910 | Line 992 | Encoding: GBK
992		@ARTICLE{Egberts1988,
993		author = {E. Egberts and H. J. C. Berendsen},
994		title = {Molecular-Dynamics Simulation of a Smectic Liquid-Crystal with Atomic
995	<	Detail},
995	>	Detail},
996		journal = {Journal of Chemical Physics},
997		year = {1988},
998		volume = {89},
#	Line 938 | Line 1020 | Encoding: GBK
1020		@ARTICLE{Fennell2004,
1021		author = {C. J. Fennell and J. D. Gezelter},
1022		title = {On the structural and transport properties of the soft sticky dipole
1023	<	and related single-point water models},
1023	>	and related single-point water models},
1024		journal = {Journal of Chemical Physics},
1025		year = {2004},
1026		volume = {120},
#	Line 946 | Line 1028 | Encoding: GBK
1028		number = {19},
1029		month = {May 15},
1030		abstract = {The density maximum and temperature dependence of the self-diffusion
1031	<	constant were investigated for the soft sticky dipole (SSD) water
1032	<	model and two related reparametrizations of this single-point model.
1033	<	A combination of microcanonical and isobaric-isothermal molecular
1034	<	dynamics simulations was used to calculate these properties, both
1035	<	with and without the use of reaction field to handle long-range
1036	<	electrostatics. The isobaric-isothermal simulations of the melting
1037	<	of both ice-I-h and ice-I-c showed a density maximum near 260 K.
1038	<	In most cases, the use of the reaction field resulted in calculated
1039	<	densities which were significantly lower than experimental densities.
1040	<	Analysis of self-diffusion constants shows that the original SSD
1041	<	model captures the transport properties of experimental water very
1042	<	well in both the normal and supercooled liquid regimes. We also
1043	<	present our reparametrized versions of SSD for use both with the
1044	<	reaction field or without any long-range electrostatic corrections.
1045	<	These are called the SSD/RF and SSD/E models, respectively. These
1046	<	modified models were shown to maintain or improve upon the experimental
1047	<	agreement with the structural and transport properties that can
1048	<	be obtained with either the original SSD or the density-corrected
1049	<	version of the original model (SSD1). Additionally, a novel low-density
1050	<	ice structure is presented which appears to be the most stable ice
1051	<	structure for the entire SSD family. (C) 2004 American Institute
1052	<	of Physics.},
1031	>	constant were investigated for the soft sticky dipole (SSD) water
1032	>	model and two related reparametrizations of this single-point model.
1033	>	A combination of microcanonical and isobaric-isothermal molecular
1034	>	dynamics simulations was used to calculate these properties, both
1035	>	with and without the use of reaction field to handle long-range
1036	>	electrostatics. The isobaric-isothermal simulations of the melting
1037	>	of both ice-I-h and ice-I-c showed a density maximum near 260 K.
1038	>	In most cases, the use of the reaction field resulted in calculated
1039	>	densities which were significantly lower than experimental densities.
1040	>	Analysis of self-diffusion constants shows that the original SSD
1041	>	model captures the transport properties of experimental water very
1042	>	well in both the normal and supercooled liquid regimes. We also
1043	>	present our reparametrized versions of SSD for use both with the
1044	>	reaction field or without any long-range electrostatic corrections.
1045	>	These are called the SSD/RF and SSD/E models, respectively. These
1046	>	modified models were shown to maintain or improve upon the experimental
1047	>	agreement with the structural and transport properties that can
1048	>	be obtained with either the original SSD or the density-corrected
1049	>	version of the original model (SSD1). Additionally, a novel low-density
1050	>	ice structure is presented which appears to be the most stable ice
1051	>	structure for the entire SSD family. (C) 2004 American Institute
1052	>	of Physics.},
1053		annote = {816YY Times Cited:5 Cited References Count:39},
1054		issn = {0021-9606},
1055		uri = {<Go to ISI>://000221146400032},
#	Line 976 | Line 1058 | Encoding: GBK
1058		@ARTICLE{Fernandes2002,
1059		author = {M. X. Fernandes and J. G. {de la Torre}},
1060		title = {Brownian dynamics simulation of rigid particles of arbitrary shape
1061	<	in external fields},
1061	>	in external fields},
1062		journal = {Biophysical Journal},
1063		year = {2002},
1064		volume = {83},
#	Line 984 | Line 1066 | Encoding: GBK
1066		number = {6},
1067		month = {Dec},
1068		abstract = {We have developed a Brownian dynamics simulation algorithm to generate
1069	<	Brownian trajectories of an isolated, rigid particle of arbitrary
1070	<	shape in the presence of electric fields or any other external agents.
1071	<	Starting from the generalized diffusion tensor, which can be calculated
1072	<	with the existing HYDRO software, the new program BROWNRIG (including
1073	<	a case-specific subprogram for the external agent) carries out a
1074	<	simulation that is analyzed later to extract the observable dynamic
1075	<	properties. We provide a variety of examples of utilization of this
1076	<	method, which serve as tests of its performance, and also illustrate
1077	<	its applicability. Examples include free diffusion, transport in
1078	<	an electric field, and diffusion in a restricting environment.},
1069	>	Brownian trajectories of an isolated, rigid particle of arbitrary
1070	>	shape in the presence of electric fields or any other external agents.
1071	>	Starting from the generalized diffusion tensor, which can be calculated
1072	>	with the existing HYDRO software, the new program BROWNRIG (including
1073	>	a case-specific subprogram for the external agent) carries out a
1074	>	simulation that is analyzed later to extract the observable dynamic
1075	>	properties. We provide a variety of examples of utilization of this
1076	>	method, which serve as tests of its performance, and also illustrate
1077	>	its applicability. Examples include free diffusion, transport in
1078	>	an electric field, and diffusion in a restricting environment.},
1079		annote = {633AD Times Cited:2 Cited References Count:43},
1080		issn = {0006-3495},
1081		uri = {<Go to ISI>://000180256300012},
#	Line 1002 | Line 1084 | Encoding: GBK
1084		@ARTICLE{Gay1981,
1085		author = {J. G. Gay and B. J. Berne},
1086		title = {Modification of the Overlap Potential to Mimic a Linear Site-Site
1087	<	Potential},
1087	>	Potential},
1088		journal = {Journal of Chemical Physics},
1089		year = {1981},
1090		volume = {74},
#	Line 1023 | Line 1105 | Encoding: GBK
1105		number = {6},
1106		month = {Nov},
1107		abstract = {To investigate the influence of inertial effects on the dynamics of
1108	<	an assembly of beads subjected to rigid constraints and placed in
1109	<	a buffer medium, a convenient method to introduce suitable generalized
1110	<	coordinates is presented. Without any restriction on the nature
1111	<	of the soft forces involved (both stochastic and deterministic),
1112	<	pertinent Langevin equations are derived. Provided that the Brownian
1113	<	forces are Gaussian and Markovian, the corresponding Fokker-Planck
1114	<	equation (FPE) is obtained in the complete phase space of generalized
1115	<	coordinates and momenta. The correct short time behavior for correlation
1116	<	functions (CFs) of generalized coordinates is established, and the
1117	<	diffusion equation with memory (DEM) is deduced from the FPE in
1118	<	the high friction Limit. The DEM is invoked to perform illustrative
1119	<	calculations in two dimensions of the orientational CFs for once
1120	<	broken nonrigid rods immobilized on a surface. These calculations
1121	<	reveal that the CFs under certain conditions exhibit an oscillatory
1122	<	behavior, which is irreproducible within the standard diffusion
1123	<	equation. Several methods are considered for the approximate solution
1124	<	of the DEM, and their application to three dimensional DEMs is discussed.},
1108	>	an assembly of beads subjected to rigid constraints and placed in
1109	>	a buffer medium, a convenient method to introduce suitable generalized
1110	>	coordinates is presented. Without any restriction on the nature
1111	>	of the soft forces involved (both stochastic and deterministic),
1112	>	pertinent Langevin equations are derived. Provided that the Brownian
1113	>	forces are Gaussian and Markovian, the corresponding Fokker-Planck
1114	>	equation (FPE) is obtained in the complete phase space of generalized
1115	>	coordinates and momenta. The correct short time behavior for correlation
1116	>	functions (CFs) of generalized coordinates is established, and the
1117	>	diffusion equation with memory (DEM) is deduced from the FPE in
1118	>	the high friction Limit. The DEM is invoked to perform illustrative
1119	>	calculations in two dimensions of the orientational CFs for once
1120	>	broken nonrigid rods immobilized on a surface. These calculations
1121	>	reveal that the CFs under certain conditions exhibit an oscillatory
1122	>	behavior, which is irreproducible within the standard diffusion
1123	>	equation. Several methods are considered for the approximate solution
1124	>	of the DEM, and their application to three dimensional DEMs is discussed.},
1125		annote = {257MM Times Cited:2 Cited References Count:82},
1126		issn = {1022-1344},
1127		uri = {<Go to ISI>://000083785700002},
#	Line 1056 | Line 1138 | Encoding: GBK
1138
1139		@ARTICLE{Gray2003,
1140		author = {J. J. Gray and S. Moughon and C. Wang and O. Schueler-Furman and
1141	<	B. Kuhlman and C. A. Rohl and D. Baker},
1141	>	B. Kuhlman and C. A. Rohl and D. Baker},
1142		title = {Protein-protein docking with simultaneous optimization of rigid-body
1143	<	displacement and side-chain conformations},
1143	>	displacement and side-chain conformations},
1144		journal = {Journal of Molecular Biology},
1145		year = {2003},
1146		volume = {331},
#	Line 1066 | Line 1148 | Encoding: GBK
1148		number = {1},
1149		month = {Aug 1},
1150		abstract = {Protein-protein docking algorithms provide a means to elucidate structural
1151	<	details for presently unknown complexes. Here, we present and evaluate
1152	<	a new method to predict protein-protein complexes from the coordinates
1153	<	of the unbound monomer components. The method employs a low-resolution,
1154	<	rigid-body, Monte Carlo search followed by simultaneous optimization
1155	<	of backbone displacement and side-chain conformations using Monte
1156	<	Carlo minimization. Up to 10(5) independent simulations are carried
1157	<	out, and the resulting #decoys# are ranked using an energy function
1158	<	dominated by van der Waals interactions, an implicit solvation model,
1159	<	and an orientation-dependent hydrogen bonding potential. Top-ranking
1160	<	decoys are clustered to select the final predictions. Small-perturbation
1161	<	studies reveal the formation of binding funnels in 42 of 54 cases
1162	<	using coordinates derived from the bound complexes and in 32 of
1163	<	54 cases using independently determined coordinates of one or both
1164	<	monomers. Experimental binding affinities correlate with the calculated
1165	<	score function and explain the predictive success or failure of
1166	<	many targets. Global searches using one or both unbound components
1167	<	predict at least 25% of the native residue-residue contacts in 28
1168	<	of the 32 cases where binding funnels exist. The results suggest
1169	<	that the method may soon be useful for generating models of biologically
1170	<	important complexes from the structures of the isolated components,
1171	<	but they also highlight the challenges that must be met to achieve
1172	<	consistent and accurate prediction of protein-protein interactions.
1173	<	(C) 2003 Elsevier Ltd. All rights reserved.},
1151	>	details for presently unknown complexes. Here, we present and evaluate
1152	>	a new method to predict protein-protein complexes from the coordinates
1153	>	of the unbound monomer components. The method employs a low-resolution,
1154	>	rigid-body, Monte Carlo search followed by simultaneous optimization
1155	>	of backbone displacement and side-chain conformations using Monte
1156	>	Carlo minimization. Up to 10(5) independent simulations are carried
1157	>	out, and the resulting #decoys# are ranked using an energy function
1158	>	dominated by van der Waals interactions, an implicit solvation model,
1159	>	and an orientation-dependent hydrogen bonding potential. Top-ranking
1160	>	decoys are clustered to select the final predictions. Small-perturbation
1161	>	studies reveal the formation of binding funnels in 42 of 54 cases
1162	>	using coordinates derived from the bound complexes and in 32 of
1163	>	54 cases using independently determined coordinates of one or both
1164	>	monomers. Experimental binding affinities correlate with the calculated
1165	>	score function and explain the predictive success or failure of
1166	>	many targets. Global searches using one or both unbound components
1167	>	predict at least 25% of the native residue-residue contacts in 28
1168	>	of the 32 cases where binding funnels exist. The results suggest
1169	>	that the method may soon be useful for generating models of biologically
1170	>	important complexes from the structures of the isolated components,
1171	>	but they also highlight the challenges that must be met to achieve
1172	>	consistent and accurate prediction of protein-protein interactions.
1173	>	(C) 2003 Elsevier Ltd. All rights reserved.},
1174		annote = {704QL Times Cited:48 Cited References Count:60},
1175		issn = {0022-2836},
1176		uri = {<Go to ISI>://000184351300022},
1177		}
1178
1179	+	@ARTICLE{Greengard1994,
1180	+	author = {L. Greengard},
1181	+	title = {Fast Algorithms for Classical Physics},
1182	+	journal = {Science},
1183	+	year = {1994},
1184	+	volume = {265},
1185	+	pages = {909-914},
1186	+	number = {5174},
1187	+	month = {Aug 12},
1188	+	abstract = {Some of the recently developed fast summation methods that have arisen
1189	+	in scientific computing are described. These methods require an
1190	+	amount of work proportional to N or N log N to evaluate all pairwise
1191	+	interactions in an ensemble of N particles. Traditional methods,
1192	+	by contrast, require an amount of work proportional to N-2. AS a
1193	+	result, large-scale simulations can be carried out using only modest
1194	+	computer resources. In combination with supercomputers, it is possible
1195	+	to address questions that were previously out of reach. Problems
1196	+	from diffusion, gravitation, and wave propagation are considered.},
1197	+	annote = {Pb499 Times Cited:99 Cited References Count:44},
1198	+	issn = {0036-8075},
1199	+	uri = {<Go to ISI>://A1994PB49900031},
1200	+	}
1201	+
1202	+	@ARTICLE{Greengard1987,
1203	+	author = {L. Greengard and V. Rokhlin},
1204	+	title = {A Fast Algorithm for Particle Simulations},
1205	+	journal = {Journal of Computational Physics},
1206	+	year = {1987},
1207	+	volume = {73},
1208	+	pages = {325-348},
1209	+	number = {2},
1210	+	month = {Dec},
1211	+	annote = {L0498 Times Cited:899 Cited References Count:7},
1212	+	issn = {0021-9991},
1213	+	uri = {<Go to ISI>://A1987L049800006},
1214	+	}
1215	+
1216	+	@ARTICLE{Hairer1997,
1217	+	author = {E. Hairer and C. Lubich},
1218	+	title = {The life-span of backward error analysis for numerical integrators},
1219	+	journal = {Numerische Mathematik},
1220	+	year = {1997},
1221	+	volume = {76},
1222	+	pages = {441-462},
1223	+	number = {4},
1224	+	month = {Jun},
1225	+	abstract = {Backward error analysis is a useful tool for the study of numerical
1226	+	approximations to ordinary differential equations. The numerical
1227	+	solution is formally interpreted as the exact solution of a perturbed
1228	+	differential equation, given as a formal and usually divergent series
1229	+	in powers of the step size. For a rigorous analysis, this series
1230	+	has to be truncated. In this article we study the influence of this
1231	+	truncation to the difference between the numerical solution and
1232	+	the exact solution of the perturbed differential equation. Results
1233	+	on the long-time behaviour of numerical solutions are obtained in
1234	+	this way. We present applications to the numerical phase portrait
1235	+	near hyperbolic equilibrium points, to asymptotically stable periodic
1236	+	orbits and Hopf bifurcation, and to energy conservation and approximation
1237	+	of invariant tori in Hamiltonian systems.},
1238	+	annote = {Xj488 Times Cited:50 Cited References Count:19},
1239	+	issn = {0029-599X},
1240	+	uri = {<Go to ISI>://A1997XJ48800002},
1241	+	}
1242	+
1243		@ARTICLE{Hao1993,
1244		author = {M. H. Hao and M. R. Pincus and S. Rackovsky and H. A. Scheraga},
1245		title = {Unfolding and Refolding of the Native Structure of Bovine Pancreatic
1246	<	Trypsin-Inhibitor Studied by Computer-Simulations},
1246	>	Trypsin-Inhibitor Studied by Computer-Simulations},
1247		journal = {Biochemistry},
1248		year = {1993},
1249		volume = {32},
#	Line 1105 | Line 1251 | Encoding: GBK
1251		number = {37},
1252		month = {Sep 21},
1253		abstract = {A new procedure for studying the folding and unfolding of proteins,
1254	<	with an application to bovine pancreatic trypsin inhibitor (BPTI),
1255	<	is reported. The unfolding and refolding of the native structure
1256	<	of the protein are characterized by the dimensions of the protein,
1257	<	expressed in terms of the three principal radii of the structure
1258	<	considered as an ellipsoid. A dynamic equation, describing the variations
1259	<	of the principal radii on the unfolding path, and a numerical procedure
1260	<	to solve this equation are proposed. Expanded and distorted conformations
1261	<	are refolded to the native structure by a dimensional-constraint
1262	<	energy minimization procedure. A unique and reproducible unfolding
1263	<	pathway for an intermediate of BPTI lacking the [30,51] disulfide
1264	<	bond is obtained. The resulting unfolded conformations are extended;
1265	<	they contain near-native local structure, but their longest principal
1266	<	radii are more than 2.5 times greater than that of the native structure.
1267	<	The most interesting finding is that the majority of expanded conformations,
1268	<	generated under various conditions, can be refolded closely to the
1269	<	native structure, as measured by the correct overall chain fold,
1270	<	by the rms deviations from the native structure of only 1.9-3.1
1271	<	angstrom, and by the energy differences of about 10 kcal/mol from
1272	<	the native structure. Introduction of the [30,51] disulfide bond
1273	<	at this stage, followed by minimization, improves the closeness
1274	<	of the refolded structures to the native structure, reducing the
1275	<	rms deviations to 0.9-2.0 angstrom. The unique refolding of these
1276	<	expanded structures over such a large conformational space implies
1277	<	that the folding is strongly dictated by the interactions in the
1278	<	amino acid sequence of BPTI. The simulations indicate that, under
1279	<	conditions that favor a compact structure as mimicked by the volume
1280	<	constraints in our algorithm; the expanded conformations have a
1281	<	strong tendency to move toward the native structure; therefore,
1282	<	they probably would be favorable folding intermediates. The results
1283	<	presented here support a general model for protein folding, i.e.,
1284	<	progressive formation of partially folded structural units, followed
1285	<	by collapse to the compact native structure. The general applicability
1286	<	of the procedure is also discussed.},
1254	>	with an application to bovine pancreatic trypsin inhibitor (BPTI),
1255	>	is reported. The unfolding and refolding of the native structure
1256	>	of the protein are characterized by the dimensions of the protein,
1257	>	expressed in terms of the three principal radii of the structure
1258	>	considered as an ellipsoid. A dynamic equation, describing the variations
1259	>	of the principal radii on the unfolding path, and a numerical procedure
1260	>	to solve this equation are proposed. Expanded and distorted conformations
1261	>	are refolded to the native structure by a dimensional-constraint
1262	>	energy minimization procedure. A unique and reproducible unfolding
1263	>	pathway for an intermediate of BPTI lacking the [30,51] disulfide
1264	>	bond is obtained. The resulting unfolded conformations are extended;
1265	>	they contain near-native local structure, but their longest principal
1266	>	radii are more than 2.5 times greater than that of the native structure.
1267	>	The most interesting finding is that the majority of expanded conformations,
1268	>	generated under various conditions, can be refolded closely to the
1269	>	native structure, as measured by the correct overall chain fold,
1270	>	by the rms deviations from the native structure of only 1.9-3.1
1271	>	angstrom, and by the energy differences of about 10 kcal/mol from
1272	>	the native structure. Introduction of the [30,51] disulfide bond
1273	>	at this stage, followed by minimization, improves the closeness
1274	>	of the refolded structures to the native structure, reducing the
1275	>	rms deviations to 0.9-2.0 angstrom. The unique refolding of these
1276	>	expanded structures over such a large conformational space implies
1277	>	that the folding is strongly dictated by the interactions in the
1278	>	amino acid sequence of BPTI. The simulations indicate that, under
1279	>	conditions that favor a compact structure as mimicked by the volume
1280	>	constraints in our algorithm; the expanded conformations have a
1281	>	strong tendency to move toward the native structure; therefore,
1282	>	they probably would be favorable folding intermediates. The results
1283	>	presented here support a general model for protein folding, i.e.,
1284	>	progressive formation of partially folded structural units, followed
1285	>	by collapse to the compact native structure. The general applicability
1286	>	of the procedure is also discussed.},
1287		annote = {Ly294 Times Cited:27 Cited References Count:57},
1288		issn = {0006-2960},
1289		uri = {<Go to ISI>://A1993LY29400014},
#	Line 1145 | Line 1291 | Encoding: GBK
1291
1292		@ARTICLE{Hinsen2000,
1293		author = {K. Hinsen and A. J. Petrescu and S. Dellerue and M. C. Bellissent-Funel
1294	<	and G. R. Kneller},
1294	>	and G. R. Kneller},
1295		title = {Harmonicity in slow protein dynamics},
1296		journal = {Chemical Physics},
1297		year = {2000},
#	Line 1154 | Line 1300 | Encoding: GBK
1300		number = {1-2},
1301		month = {Nov 1},
1302		abstract = {The slow dynamics of proteins around its native folded state is usually
1303	<	described by diffusion in a strongly anharmonic potential. In this
1304	<	paper, we try to understand the form and origin of the anharmonicities,
1305	<	with the principal aim of gaining a better understanding of the
1306	<	principal motion types, but also in order to develop more efficient
1307	<	numerical methods for simulating neutron scattering spectra of large
1308	<	proteins. First, we decompose a molecular dynamics (MD) trajectory
1309	<	of 1.5 ns for a C-phycocyanin dimer surrounded by a layer of water
1310	<	into three contributions that we expect to be independent: the global
1311	<	motion of the residues, the rigid-body motion of the sidechains
1312	<	relative to the backbone, and the internal deformations of the sidechains.
1313	<	We show that they are indeed almost independent by verifying the
1314	<	factorization of the incoherent intermediate scattering function.
1315	<	Then, we show that the global residue motions, which include all
1316	<	large-scale backbone motions, can be reproduced by a simple harmonic
1317	<	model which contains two contributions: a short-time vibrational
1318	<	term, described by a standard normal mode calculation in a local
1319	<	minimum, and a long-time diffusive term, described by Brownian motion
1320	<	in an effective harmonic potential. The potential and the friction
1321	<	constants were fitted to the MD data. The major anharmonic contribution
1322	<	to the incoherent intermediate scattering function comes from the
1323	<	rigid-body diffusion of the sidechains. This model can be used to
1324	<	calculate scattering functions for large proteins and for long-time
1325	<	scales very efficiently, and thus provides a useful complement to
1326	<	MD simulations, which are best suited for detailed studies on smaller
1327	<	systems or for shorter time scales. (C) 2000 Elsevier Science B.V.
1328	<	All rights reserved.},
1303	>	described by diffusion in a strongly anharmonic potential. In this
1304	>	paper, we try to understand the form and origin of the anharmonicities,
1305	>	with the principal aim of gaining a better understanding of the
1306	>	principal motion types, but also in order to develop more efficient
1307	>	numerical methods for simulating neutron scattering spectra of large
1308	>	proteins. First, we decompose a molecular dynamics (MD) trajectory
1309	>	of 1.5 ns for a C-phycocyanin dimer surrounded by a layer of water
1310	>	into three contributions that we expect to be independent: the global
1311	>	motion of the residues, the rigid-body motion of the sidechains
1312	>	relative to the backbone, and the internal deformations of the sidechains.
1313	>	We show that they are indeed almost independent by verifying the
1314	>	factorization of the incoherent intermediate scattering function.
1315	>	Then, we show that the global residue motions, which include all
1316	>	large-scale backbone motions, can be reproduced by a simple harmonic
1317	>	model which contains two contributions: a short-time vibrational
1318	>	term, described by a standard normal mode calculation in a local
1319	>	minimum, and a long-time diffusive term, described by Brownian motion
1320	>	in an effective harmonic potential. The potential and the friction
1321	>	constants were fitted to the MD data. The major anharmonic contribution
1322	>	to the incoherent intermediate scattering function comes from the
1323	>	rigid-body diffusion of the sidechains. This model can be used to
1324	>	calculate scattering functions for large proteins and for long-time
1325	>	scales very efficiently, and thus provides a useful complement to
1326	>	MD simulations, which are best suited for detailed studies on smaller
1327	>	systems or for shorter time scales. (C) 2000 Elsevier Science B.V.
1328	>	All rights reserved.},
1329		annote = {Sp. Iss. SI 368MT Times Cited:16 Cited References Count:31},
1330		issn = {0301-0104},
1331		uri = {<Go to ISI>://000090121700003},
#	Line 1195 | Line 1341 | Encoding: GBK
1341		number = {4},
1342		month = {Oct},
1343		abstract = {Evidence has been found for the existence water at the protein-lipid
1344	<	hydrophobic interface ot the membrane proteins, gramicidin and apocytochrome
1345	<	C, using two related fluorescence spectroscopic approaches. The
1346	<	first approach exploited the fact that the presence of water in
1347	<	the excited state solvent cage of a fluorophore increases the rate
1348	<	of decay. For 1,6-diphenyl-1,3,5-hexatriene (DPH) and 1-palmitoyl-2-[[2-[4-(6-phenyl-trans-1,3,5-hexatrienyl)
1349	<	phenyl]ethyl]carbonyl]-3-sn-PC (DPH-PC), where the fluorophores
1350	<	are located in the hydrophobic core of the lipid bilayer, the introduction
1351	<	of gramicidin reduced the fluorescence lifetime, indicative of an
1352	<	increased presence of water in the bilayer. Since a high protein:lipid
1353	<	ratio was used, the fluorophores were forced to be adjacent to the
1354	<	protein hydrophobic surface, hence the presence of water in this
1355	<	region could be inferred. Cholesterol is known to reduce the water
1356	<	content of lipid bilayers and this effect was maintained at the
1357	<	protein-lipid interface with both gramicidin and apocytochrome C,
1358	<	again suggesting hydration in this region. The second approach was
1359	<	to use the fluorescence enhancement induced by exchanging deuterium
1360	<	oxide (D2O) for H2O. Both the fluorescence intensities of trimethylammonium-DPH,
1361	<	located in the lipid head group region, and of the gramicidin intrinsic
1362	<	tryptophans were greater in a D2O buffer compared with H2O, showing
1363	<	that the fluorophores were exposed to water in the bilayer at the
1364	<	protein-lipid interface. In the presence of cholesterol the fluorescence
1365	<	intensity ratio of D2O to H2O decreased, indicating a removal of
1366	<	water by the cholesterol, in keeping with the lifetime data. Altered
1367	<	hydration at the protein-lipid interface could affect conformation,
1368	<	thereby offering a new route by which membrane protein functioning
1369	<	may be modified.},
1344	>	hydrophobic interface ot the membrane proteins, gramicidin and apocytochrome
1345	>	C, using two related fluorescence spectroscopic approaches. The
1346	>	first approach exploited the fact that the presence of water in
1347	>	the excited state solvent cage of a fluorophore increases the rate
1348	>	of decay. For 1,6-diphenyl-1,3,5-hexatriene (DPH) and 1-palmitoyl-2-[[2-[4-(6-phenyl-trans-1,3,5-hexatrienyl)
1349	>	phenyl]ethyl]carbonyl]-3-sn-PC (DPH-PC), where the fluorophores
1350	>	are located in the hydrophobic core of the lipid bilayer, the introduction
1351	>	of gramicidin reduced the fluorescence lifetime, indicative of an
1352	>	increased presence of water in the bilayer. Since a high protein:lipid
1353	>	ratio was used, the fluorophores were forced to be adjacent to the
1354	>	protein hydrophobic surface, hence the presence of water in this
1355	>	region could be inferred. Cholesterol is known to reduce the water
1356	>	content of lipid bilayers and this effect was maintained at the
1357	>	protein-lipid interface with both gramicidin and apocytochrome C,
1358	>	again suggesting hydration in this region. The second approach was
1359	>	to use the fluorescence enhancement induced by exchanging deuterium
1360	>	oxide (D2O) for H2O. Both the fluorescence intensities of trimethylammonium-DPH,
1361	>	located in the lipid head group region, and of the gramicidin intrinsic
1362	>	tryptophans were greater in a D2O buffer compared with H2O, showing
1363	>	that the fluorophores were exposed to water in the bilayer at the
1364	>	protein-lipid interface. In the presence of cholesterol the fluorescence
1365	>	intensity ratio of D2O to H2O decreased, indicating a removal of
1366	>	water by the cholesterol, in keeping with the lifetime data. Altered
1367	>	hydration at the protein-lipid interface could affect conformation,
1368	>	thereby offering a new route by which membrane protein functioning
1369	>	may be modified.},
1370		annote = {Ju251 Times Cited:55 Cited References Count:44},
1371		issn = {0006-3495},
1372		uri = {<Go to ISI>://A1992JU25100002},
1373		}
1374
1375	+	@BOOK{Hockney1981,
1376	+	title = {Computer Simulation Using Particles},
1377	+	publisher = {McGraw-Hill},
1378	+	year = {1981},
1379	+	author = {R.W. Hockney and J.W. Eastwood},
1380	+	address = {New York},
1381	+	}
1382	+
1383		@ARTICLE{Huh2004,
1384		author = {Y. Huh and N. M. Cann},
1385		title = {Discrimination in isotropic, nematic, and smectic phases of chiral
1386	<	calamitic molecules: A computer simulation study},
1386	>	calamitic molecules: A computer simulation study},
1387		journal = {Journal of Chemical Physics},
1388		year = {2004},
1389		volume = {121},
#	Line 1237 | Line 1391 | Encoding: GBK
1391		number = {20},
1392		month = {Nov 22},
1393		abstract = {Racemic fluids of chiral calamitic molecules are investigated with
1394	<	molecular dynamics simulations. In particular, the phase behavior
1395	<	as a function of density is examined for eight racemates. The relationship
1396	<	between chiral discrimination and orientational order in the phase
1397	<	is explored. We find that the transition from the isotropic phase
1398	<	to a liquid crystal phase is accompanied by an increase in chiral
1399	<	discrimination, as measured by differences in radial distributions.
1400	<	Among ordered phases, discrimination is largest for smectic phases
1401	<	with a significant preference for heterochiral contact within the
1402	<	layers. (C) 2004 American Institute of Physics.},
1394	>	molecular dynamics simulations. In particular, the phase behavior
1395	>	as a function of density is examined for eight racemates. The relationship
1396	>	between chiral discrimination and orientational order in the phase
1397	>	is explored. We find that the transition from the isotropic phase
1398	>	to a liquid crystal phase is accompanied by an increase in chiral
1399	>	discrimination, as measured by differences in radial distributions.
1400	>	Among ordered phases, discrimination is largest for smectic phases
1401	>	with a significant preference for heterochiral contact within the
1402	>	layers. (C) 2004 American Institute of Physics.},
1403		annote = {870FJ Times Cited:0 Cited References Count:63},
1404		issn = {0021-9606},
1405		uri = {<Go to ISI>://000225042700059},
#	Line 1261 | Line 1415 | Encoding: GBK
1415		number = {5},
1416		month = {Feb 1},
1417		abstract = {In this paper we show the possibility of using very mild stochastic
1418	<	damping to stabilize long time step integrators for Newtonian molecular
1419	<	dynamics. More specifically, stable and accurate integrations are
1420	<	obtained for damping coefficients that are only a few percent of
1421	<	the natural decay rate of processes of interest, such as the velocity
1422	<	autocorrelation function. Two new multiple time stepping integrators,
1423	<	Langevin Molly (LM) and Brunger-Brooks-Karplus-Molly (BBK-M), are
1424	<	introduced in this paper. Both use the mollified impulse method
1425	<	for the Newtonian term. LM uses a discretization of the Langevin
1426	<	equation that is exact for the constant force, and BBK-M uses the
1427	<	popular Brunger-Brooks-Karplus integrator (BBK). These integrators,
1428	<	along with an extrapolative method called LN, are evaluated across
1429	<	a wide range of damping coefficient values. When large damping coefficients
1430	<	are used, as one would for the implicit modeling of solvent molecules,
1431	<	the method LN is superior, with LM closely following. However, with
1432	<	mild damping of 0.2 ps(-1), LM produces the best results, allowing
1433	<	long time steps of 14 fs in simulations containing explicitly modeled
1434	<	flexible water. With BBK-M and the same damping coefficient, time
1435	<	steps of 12 fs are possible for the same system. Similar results
1436	<	are obtained for a solvated protein-DNA simulation of estrogen receptor
1437	<	ER with estrogen response element ERE. A parallel version of BBK-M
1438	<	runs nearly three times faster than the Verlet-I/r-RESPA (reversible
1439	<	reference system propagator algorithm) when using the largest stable
1440	<	time step on each one, and it also parallelizes well. The computation
1441	<	of diffusion coefficients for flexible water and ER/ERE shows that
1442	<	when mild damping of up to 0.2 ps-1 is used the dynamics are not
1443	<	significantly distorted. (C) 2001 American Institute of Physics.},
1418	>	damping to stabilize long time step integrators for Newtonian molecular
1419	>	dynamics. More specifically, stable and accurate integrations are
1420	>	obtained for damping coefficients that are only a few percent of
1421	>	the natural decay rate of processes of interest, such as the velocity
1422	>	autocorrelation function. Two new multiple time stepping integrators,
1423	>	Langevin Molly (LM) and Brunger-Brooks-Karplus-Molly (BBK-M), are
1424	>	introduced in this paper. Both use the mollified impulse method
1425	>	for the Newtonian term. LM uses a discretization of the Langevin
1426	>	equation that is exact for the constant force, and BBK-M uses the
1427	>	popular Brunger-Brooks-Karplus integrator (BBK). These integrators,
1428	>	along with an extrapolative method called LN, are evaluated across
1429	>	a wide range of damping coefficient values. When large damping coefficients
1430	>	are used, as one would for the implicit modeling of solvent molecules,
1431	>	the method LN is superior, with LM closely following. However, with
1432	>	mild damping of 0.2 ps(-1), LM produces the best results, allowing
1433	>	long time steps of 14 fs in simulations containing explicitly modeled
1434	>	flexible water. With BBK-M and the same damping coefficient, time
1435	>	steps of 12 fs are possible for the same system. Similar results
1436	>	are obtained for a solvated protein-DNA simulation of estrogen receptor
1437	>	ER with estrogen response element ERE. A parallel version of BBK-M
1438	>	runs nearly three times faster than the Verlet-I/r-RESPA (reversible
1439	>	reference system propagator algorithm) when using the largest stable
1440	>	time step on each one, and it also parallelizes well. The computation
1441	>	of diffusion coefficients for flexible water and ER/ERE shows that
1442	>	when mild damping of up to 0.2 ps-1 is used the dynamics are not
1443	>	significantly distorted. (C) 2001 American Institute of Physics.},
1444		annote = {397CQ Times Cited:14 Cited References Count:36},
1445		issn = {0021-9606},
1446		uri = {<Go to ISI>://000166676100020},
1447		}
1448
1449	<	@ARTICLE{Gray2003,
1450	<	author = {J.~J Gray,S. Moughon, C. Wang },
1451	<	title = {Protein-protein docking with simultaneous optimization of rigid-body
1452	<	displacement and side-chain conformations},
1453	<	journal = {jmb},
1454	<	year = {2003},
1455	<	volume = {331},
1302	<	pages = {281-299},
1449	>	@ARTICLE{Torre1977,
1450	>	author = {Jose Garcia De La Torre, V.A. Bloomfield},
1451	>	title = {Hydrodynamic properties of macromolecular complexes. I. Translation},
1452	>	journal = {Biopolymers},
1453	>	year = {1977},
1454	>	volume = {16},
1455	>	pages = {1747-1763},
1456		}
1457
1458	+	@ARTICLE{Kane2000,
1459	+	author = {C. Kane and J. E. Marsden and M. Ortiz and M. West},
1460	+	title = {Variational integrators and the Newmark algorithm for conservative
1461	+	and dissipative mechanical systems},
1462	+	journal = {International Journal for Numerical Methods in Engineering},
1463	+	year = {2000},
1464	+	volume = {49},
1465	+	pages = {1295-1325},
1466	+	number = {10},
1467	+	month = {Dec 10},
1468	+	abstract = {The purpose of this work is twofold. First, we demonstrate analytically
1469	+	that the classical Newmark family as well as related integration
1470	+	algorithms are variational in the sense of the Veselov formulation
1471	+	of discrete mechanics. Such variational algorithms are well known
1472	+	to be symplectic and momentum preserving and to often have excellent
1473	+	global energy behaviour. This analytical result is verified through
1474	+	numerical examples and is believed to be one of the primary reasons
1475	+	that this class of algorithms performs so well. Second, we develop
1476	+	algorithms for mechanical systems with forcing, and in particular,
1477	+	for dissipative systems. In this case, we develop integrators that
1478	+	are based on a discretization of the Lagrange d'Alembert principle
1479	+	as well as on a variational formulation of dissipation. It is demonstrated
1480	+	that these types of structured integrators have good numerical behaviour
1481	+	in terms of obtaining the correct amounts by which the energy changes
1482	+	over the integration run. Copyright (C) 2000 John Wiley & Sons,
1483	+	Ltd.},
1484	+	annote = {373CJ Times Cited:30 Cited References Count:41},
1485	+	issn = {0029-5981},
1486	+	uri = {<Go to ISI>://000165270600004},
1487	+	}
1488	+
1489		@ARTICLE{Klimov1997,
1490		author = {D. K. Klimov and D. Thirumalai},
1491		title = {Viscosity dependence of the folding rates of proteins},
#	Line 1312 | Line 1496 | Encoding: GBK
1496		number = {2},
1497		month = {Jul 14},
1498		abstract = {The viscosity (eta) dependence of the folding rates for four sequences
1499	<	(the native state of three sequences is a beta sheet, while the
1500	<	fourth forms an alpha helix) is calculated for off-lattice models
1501	<	of proteins. Assuming that the dynamics is given by the Langevin
1502	<	equation, we show that the folding rates increase linearly at low
1503	<	viscosities eta, decrease as 1/eta at large eta, and have a maximum
1504	<	at intermediate values. The Kramers' theory of barrier crossing
1505	<	provides a quantitative fit of the numerical results. By mapping
1506	<	the simulation results to real proteins we estimate that for optimized
1507	<	sequences the time scale for forming a four turn alpha-helix topology
1508	<	is about 500 ns, whereas for beta sheet it is about 10 mu s.},
1499	>	(the native state of three sequences is a beta sheet, while the
1500	>	fourth forms an alpha helix) is calculated for off-lattice models
1501	>	of proteins. Assuming that the dynamics is given by the Langevin
1502	>	equation, we show that the folding rates increase linearly at low
1503	>	viscosities eta, decrease as 1/eta at large eta, and have a maximum
1504	>	at intermediate values. The Kramers' theory of barrier crossing
1505	>	provides a quantitative fit of the numerical results. By mapping
1506	>	the simulation results to real proteins we estimate that for optimized
1507	>	sequences the time scale for forming a four turn alpha-helix topology
1508	>	is about 500 ns, whereas for beta sheet it is about 10 mu s.},
1509		annote = {Xk293 Times Cited:77 Cited References Count:17},
1510		issn = {0031-9007},
1511		uri = {<Go to ISI>://A1997XK29300035},
1512		}
1513
1514	+	@ARTICLE{Kol1997,
1515	+	author = {A. Kol and B. B. Laird and B. J. Leimkuhler},
1516	+	title = {A symplectic method for rigid-body molecular simulation},
1517	+	journal = {Journal of Chemical Physics},
1518	+	year = {1997},
1519	+	volume = {107},
1520	+	pages = {2580-2588},
1521	+	number = {7},
1522	+	month = {Aug 15},
1523	+	abstract = {Rigid-body molecular dynamics simulations typically are performed
1524	+	in a quaternion representation. The nonseparable form of the Hamiltonian
1525	+	in quaternions prevents the use of a standard leapfrog (Verlet)
1526	+	integrator, so nonsymplectic Runge-Kutta, multistep, or extrapolation
1527	+	methods are generally used, This is unfortunate since symplectic
1528	+	methods like Verlet exhibit superior energy conservation in long-time
1529	+	integrations. In this article, we describe an alternative method,
1530	+	which we call RSHAKE (for rotation-SHAKE), in which the entire rotation
1531	+	matrix is evolved (using the scheme of McLachlan and Scovel [J.
1532	+	Nonlin. Sci, 16 233 (1995)]) in tandem with the particle positions.
1533	+	We employ a fast approximate Newton solver to preserve the orthogonality
1534	+	of the rotation matrix. We test our method on a system of soft-sphere
1535	+	dipoles and compare with quaternion evolution using a 4th-order
1536	+	predictor-corrector integrator, Although the short-time error of
1537	+	the quaternion algorithm is smaller for fixed time step than that
1538	+	for RSHAKE, the quaternion scheme exhibits an energy drift which
1539	+	is not observed in simulations with RSHAKE, hence a fixed energy
1540	+	tolerance can be achieved by using a larger time step, The superiority
1541	+	of RSHAKE increases with system size. (C) 1997 American Institute
1542	+	of Physics.},
1543	+	annote = {Xq332 Times Cited:11 Cited References Count:18},
1544	+	issn = {0021-9606},
1545	+	uri = {<Go to ISI>://A1997XQ33200046},
1546	+	}
1547	+
1548		@ARTICLE{Lansac2001,
1549		author = {Y. Lansac and M. A. Glaser and N. A. Clark},
1550		title = {Microscopic structure and dynamics of a partial bilayer smectic liquid
1551	<	crystal},
1551	>	crystal},
1552		journal = {Physical Review E},
1553		year = {2001},
1554		volume = {6405},
#	Line 1338 | Line 1556 | Encoding: GBK
1556		number = {5},
1557		month = {Nov},
1558		abstract = {Cyanobiphenyls (nCB's) represent a useful and intensively studied
1559	<	class of mesogens. Many of the peculiar properties of nCB's (e.g.,
1560	<	the occurence of the partial bilayer smectic-A(d) phase) are thought
1561	<	to be a manifestation of short-range antiparallel association of
1562	<	neighboring molecules, resulting from strong dipole-dipole interactions
1563	<	between cyano groups. To test and extend existing models of microscopic
1564	<	ordering in nCB's, we carry out large-scale atomistic simulation
1565	<	studies of the microscopic structure and dynamics of the Sm-A(d)
1566	<	phase of 4-octyl-4'-cyanobiphenyl (8CB). We compute a variety of
1567	<	thermodynamic, structural, and dynamical properties for this material,
1568	<	and make a detailed comparison of our results with experimental
1569	<	measurements in order to validate our molecular model. Semiquantitative
1570	<	agreement with experiment is found: the smectic layer spacing and
1571	<	mass density are well reproduced, translational diffusion constants
1572	<	are similar to experiment, but the orientational ordering of alkyl
1573	<	chains is overestimated. This simulation provides a detailed picture
1574	<	of molecular conformation, smectic layer structure, and intermolecular
1575	<	correlations in Sm-A(d) 8CB, and demonstrates that pronounced short-range
1576	<	antiparallel association of molecules arising from dipole-dipole
1577	<	interactions plays a dominant role in determining the molecular-scale
1578	<	structure of 8CB.},
1559	>	class of mesogens. Many of the peculiar properties of nCB's (e.g.,
1560	>	the occurence of the partial bilayer smectic-A(d) phase) are thought
1561	>	to be a manifestation of short-range antiparallel association of
1562	>	neighboring molecules, resulting from strong dipole-dipole interactions
1563	>	between cyano groups. To test and extend existing models of microscopic
1564	>	ordering in nCB's, we carry out large-scale atomistic simulation
1565	>	studies of the microscopic structure and dynamics of the Sm-A(d)
1566	>	phase of 4-octyl-4'-cyanobiphenyl (8CB). We compute a variety of
1567	>	thermodynamic, structural, and dynamical properties for this material,
1568	>	and make a detailed comparison of our results with experimental
1569	>	measurements in order to validate our molecular model. Semiquantitative
1570	>	agreement with experiment is found: the smectic layer spacing and
1571	>	mass density are well reproduced, translational diffusion constants
1572	>	are similar to experiment, but the orientational ordering of alkyl
1573	>	chains is overestimated. This simulation provides a detailed picture
1574	>	of molecular conformation, smectic layer structure, and intermolecular
1575	>	correlations in Sm-A(d) 8CB, and demonstrates that pronounced short-range
1576	>	antiparallel association of molecules arising from dipole-dipole
1577	>	interactions plays a dominant role in determining the molecular-scale
1578	>	structure of 8CB.},
1579		annote = {Part 1 496QF Times Cited:10 Cited References Count:60},
1580		issn = {1063-651X},
1581		uri = {<Go to ISI>://000172406900063},
#	Line 1373 | Line 1591 | Encoding: GBK
1591		number = {1},
1592		month = {Jan},
1593		abstract = {Recently, a new class of smectic liquid crystal phases characterized
1594	<	by the spontaneous formation of macroscopic chiral domains from
1595	<	achiral bent-core molecules has been discovered. We have carried
1596	<	out Monte Carlo simulations of a minimal hard spherocylinder dimer
1597	<	model to investigate the role of excluded volume interactions in
1598	<	determining the phase behavior of bent-core materials and to probe
1599	<	the molecular origins of polar and chiral symmetry breaking. We
1600	<	present the phase diagram of hard spherocylinder dimers of length-diameter
1601	<	ratio of 5 as a function of pressure or density and dimer opening
1602	<	angle psi. With decreasing psi, a transition from a nonpolar to
1603	<	a polar smectic A phase is observed near psi=167degrees, and the
1604	<	nematic phase becomes thermodynamically unstable for psi<135degrees.
1605	<	Free energy calculations indicate that the antipolar smectic A (SmAP(A))
1606	<	phase is more stable than the polar smectic A phase (SmAP(F)). No
1607	<	chiral smectic or biaxial nematic phases were found.},
1594	>	by the spontaneous formation of macroscopic chiral domains from
1595	>	achiral bent-core molecules has been discovered. We have carried
1596	>	out Monte Carlo simulations of a minimal hard spherocylinder dimer
1597	>	model to investigate the role of excluded volume interactions in
1598	>	determining the phase behavior of bent-core materials and to probe
1599	>	the molecular origins of polar and chiral symmetry breaking. We
1600	>	present the phase diagram of hard spherocylinder dimers of length-diameter
1601	>	ratio of 5 as a function of pressure or density and dimer opening
1602	>	angle psi. With decreasing psi, a transition from a nonpolar to
1603	>	a polar smectic A phase is observed near psi=167degrees, and the
1604	>	nematic phase becomes thermodynamically unstable for psi<135degrees.
1605	>	Free energy calculations indicate that the antipolar smectic A (SmAP(A))
1606	>	phase is more stable than the polar smectic A phase (SmAP(F)). No
1607	>	chiral smectic or biaxial nematic phases were found.},
1608		annote = {Part 1 646CM Times Cited:15 Cited References Count:38},
1609		issn = {1063-651X},
1610		uri = {<Go to ISI>://000181017300042},
#	Line 1401 | Line 1619 | Encoding: GBK
1619		edition = {2nd},
1620		}
1621
1622	+	@ARTICLE{Leimkuhler1999,
1623	+	author = {B. Leimkuhler},
1624	+	title = {Reversible adaptive regularization: perturbed Kepler motion and classical
1625	+	atomic trajectories},
1626	+	journal = {Philosophical Transactions of the Royal Society of London Series
1627	+	a-Mathematical Physical and Engineering Sciences},
1628	+	year = {1999},
1629	+	volume = {357},
1630	+	pages = {1101-1133},
1631	+	number = {1754},
1632	+	month = {Apr 15},
1633	+	abstract = {Reversible and adaptive integration methods based on Kustaanheimo-Stiefel
1634	+	regularization and modified Sundman transformations are applied
1635	+	to simulate general perturbed Kepler motion and to compute classical
1636	+	trajectories of atomic systems (e.g. Rydberg atoms). The new family
1637	+	of reversible adaptive regularization methods also conserves angular
1638	+	momentum and exhibits superior energy conservation and numerical
1639	+	stability in long-time integrations. The schemes are appropriate
1640	+	for scattering, for astronomical calculations of escape time and
1641	+	long-term stability, and for classical and semiclassical studies
1642	+	of atomic dynamics. The components of an algorithm for trajectory
1643	+	calculations are described. Numerical experiments illustrate the
1644	+	effectiveness of the reversible approach.},
1645	+	annote = {199EE Times Cited:11 Cited References Count:48},
1646	+	issn = {1364-503X},
1647	+	uri = {<Go to ISI>://000080466800007},
1648	+	}
1649	+
1650		@BOOK{Leimkuhler2004,
1651		title = {Simulating Hamiltonian Dynamics},
1652		publisher = {Cambridge University Press},
#	Line 1411 | Line 1657 | Encoding: GBK
1657
1658		@ARTICLE{Levelut1981,
1659		author = {A. M. Levelut and R. J. Tarento and F. Hardouin and M. F. Achard
1660	<	and G. Sigaud},
1660	>	and G. Sigaud},
1661		title = {Number of Sa Phases},
1662		journal = {Physical Review A},
1663		year = {1981},
#	Line 1426 | Line 1672 | Encoding: GBK
1672		@ARTICLE{Lieb1982,
1673		author = {W. R. Lieb and M. Kovalycsik and R. Mendelsohn},
1674		title = {Do Clinical-Levels of General-Anesthetics Affect Lipid Bilayers -
1675	<	Evidence from Raman-Scattering},
1675	>	Evidence from Raman-Scattering},
1676		journal = {Biochimica Et Biophysica Acta},
1677		year = {1982},
1678		volume = {688},
#	Line 1439 | Line 1685 | Encoding: GBK
1685
1686		@ARTICLE{Link1997,
1687		author = {D. R. Link and G. Natale and R. Shao and J. E. Maclennan and N. A.
1688	<	Clark and E. Korblova and D. M. Walba},
1688	>	Clark and E. Korblova and D. M. Walba},
1689		title = {Spontaneous formation of macroscopic chiral domains in a fluid smectic
1690	<	phase of achiral molecules},
1690	>	phase of achiral molecules},
1691		journal = {Science},
1692		year = {1997},
1693		volume = {278},
#	Line 1449 | Line 1695 | Encoding: GBK
1695		number = {5345},
1696		month = {Dec 12},
1697		abstract = {A smectic liquid-crystal phase made from achiral molecules with bent
1698	<	cores was found to have fluid layers that exhibit two spontaneous
1699	<	symmetry-breaking instabilities: polar molecular orientational ordering
1700	<	about the layer normal and molecular tilt. These instabilities combine
1701	<	to form a chiral layer structure with a handedness that depends
1702	<	on the sign of the tilt. The bulk states are either antiferroelectric-racemic,
1703	<	with the layer polar direction and handedness alternating in sign
1704	<	from layer to layer, or antiferroelectric-chiral, which is of uniform
1705	<	layer handedness. Both states exhibit an electric field-induced
1706	<	transition from antiferroelectric to ferroelectric.},
1698	>	cores was found to have fluid layers that exhibit two spontaneous
1699	>	symmetry-breaking instabilities: polar molecular orientational ordering
1700	>	about the layer normal and molecular tilt. These instabilities combine
1701	>	to form a chiral layer structure with a handedness that depends
1702	>	on the sign of the tilt. The bulk states are either antiferroelectric-racemic,
1703	>	with the layer polar direction and handedness alternating in sign
1704	>	from layer to layer, or antiferroelectric-chiral, which is of uniform
1705	>	layer handedness. Both states exhibit an electric field-induced
1706	>	transition from antiferroelectric to ferroelectric.},
1707		annote = {Yl002 Times Cited:407 Cited References Count:25},
1708		issn = {0036-8075},
1709		uri = {<Go to ISI>://A1997YL00200028},
#	Line 1466 | Line 1712 | Encoding: GBK
1712		@ARTICLE{Liwo2005,
1713		author = {A. Liwo and M. Khalili and H. A. Scheraga},
1714		title = {Ab initio simulations of protein folding pathways by molecular dynamics
1715	<	with the united-residue (UNRES) model of polypeptide chains},
1715	>	with the united-residue (UNRES) model of polypeptide chains},
1716		journal = {Febs Journal},
1717		year = {2005},
1718		volume = {272},
#	Line 1477 | Line 1723 | Encoding: GBK
1723		uri = {<Go to ISI>://000234826102043},
1724		}
1725
1726	+	@ARTICLE{Luty1994,
1727	+	author = {B. A. Luty and M. E. Davis and I. G. Tironi and W. F. Vangunsteren},
1728	+	title = {A Comparison of Particle-Particle, Particle-Mesh and Ewald Methods
1729	+	for Calculating Electrostatic Interactions in Periodic Molecular-Systems},
1730	+	journal = {Molecular Simulation},
1731	+	year = {1994},
1732	+	volume = {14},
1733	+	pages = {11-20},
1734	+	number = {1},
1735	+	abstract = {We compare the Particle-Particle Particle-Mesh (PPPM) and Ewald methods
1736	+	for calculating electrostatic interactions in periodic molecular
1737	+	systems. A brief comparison of the theories shows that the methods
1738	+	are very similar differing mainly in the technique which is used
1739	+	to perform the ''k-space'' or mesh calculation. Because the PPPM
1740	+	utilizes the highly efficient numerical Fast Fourier Transform (FFT)
1741	+	method it requires significantly less computational effort than
1742	+	the Ewald method and scale's almost linearly with system size.},
1743	+	annote = {Qf464 Times Cited:50 Cited References Count:20},
1744	+	issn = {0892-7022},
1745	+	uri = {<Go to ISI>://A1994QF46400002},
1746	+	}
1747	+
1748		@BOOK{Marion1990,
1749		title = {Classical Dynamics of Particles and Systems},
1750		publisher = {Academic Press},
#	Line 1486 | Line 1754 | Encoding: GBK
1754		edition = {2rd},
1755		}
1756
1757	+	@ARTICLE{Marsden1998,
1758	+	author = {J. E. Marsden and G. W. Patrick and S. Shkoller},
1759	+	title = {Multisymplectic geometry, variational integrators, and nonlinear
1760	+	PDEs},
1761	+	journal = {Communications in Mathematical Physics},
1762	+	year = {1998},
1763	+	volume = {199},
1764	+	pages = {351-395},
1765	+	number = {2},
1766	+	month = {Dec},
1767	+	abstract = {This paper presents a geometric-variational approach to continuous
1768	+	and discrete mechanics and field theories. Using multisymplectic
1769	+	geometry, we show that the existence of the fundamental geometric
1770	+	structures as well as their preservation along solutions can be
1771	+	obtained directly from the variational principle. In particular,
1772	+	we prove that a unique multisymplectic structure is obtained by
1773	+	taking the derivative of an action function, and use this structure
1774	+	to prove covariant generalizations of conservation of symplecticity
1775	+	and Noether's theorem. Natural discretization schemes for PDEs,
1776	+	which have these important preservation properties, then follow
1777	+	by choosing a discrete action functional. In the case of mechanics,
1778	+	we recover the variational symplectic integrators of Veselov type,
1779	+	while for PDEs we obtain covariant spacetime integrators which conserve
1780	+	the corresponding discrete multisymplectic form as well as the discrete
1781	+	momentum mappings corresponding to symmetries. We show that the
1782	+	usual notion of symplecticity along an infinite-dimensional space
1783	+	of fields can be naturally obtained by making a spacetime split.
1784	+	All of the aspects of our method are demonstrated with a nonlinear
1785	+	sine-Gordon equation, including computational results and a comparison
1786	+	with other discretization schemes.},
1787	+	annote = {154RH Times Cited:88 Cited References Count:36},
1788	+	issn = {0010-3616},
1789	+	uri = {<Go to ISI>://000077902200006},
1790	+	}
1791	+
1792		@ARTICLE{McLachlan1993,
1793		author = {R.~I McLachlan},
1794		title = {Explicit Lie-Poisson integration and the Euler equations},
#	Line 1495 | Line 1798 | Encoding: GBK
1798		pages = {3043-3046},
1799		}
1800
1801	+	@ARTICLE{McLachlan1998a,
1802	+	author = {R. I. McLachlan and G. R. W. Quispel},
1803	+	title = {Generating functions for dynamical systems with symmetries, integrals,
1804	+	and differential invariants},
1805	+	journal = {Physica D},
1806	+	year = {1998},
1807	+	volume = {112},
1808	+	pages = {298-309},
1809	+	number = {1-2},
1810	+	month = {Jan 15},
1811	+	abstract = {We give a survey and some new examples of generating functions for
1812	+	systems with symplectic structure, systems with a first integral,
1813	+	systems that preserve volume, and systems with symmetries and/or
1814	+	time-reversing symmetries. Both ODEs and maps are treated, and we
1815	+	discuss how generating functions may be used in the structure-preserving
1816	+	numerical integration of ODEs with the above properties.},
1817	+	annote = {Yt049 Times Cited:7 Cited References Count:26},
1818	+	issn = {0167-2789},
1819	+	uri = {<Go to ISI>://000071558900021},
1820	+	}
1821	+
1822	+	@ARTICLE{McLachlan1998,
1823	+	author = {R. I. McLachlan and G. R. W. Quispel and G. S. Turner},
1824	+	title = {Numerical integrators that preserve symmetries and reversing symmetries},
1825	+	journal = {Siam Journal on Numerical Analysis},
1826	+	year = {1998},
1827	+	volume = {35},
1828	+	pages = {586-599},
1829	+	number = {2},
1830	+	month = {Apr},
1831	+	abstract = {We consider properties of flows, the relationships between them, and
1832	+	whether numerical integrators can be made to preserve these properties.
1833	+	This is done in the context of automorphisms and antiautomorphisms
1834	+	of a certain group generated by maps associated to vector fields.
1835	+	This new framework unifies several known constructions. We also
1836	+	use the concept of #covariance# of a numerical method with respect
1837	+	to a group of coordinate transformations. The main application is
1838	+	to explore the relationship between spatial symmetries, reversing
1839	+	symmetries, and time symmetry of flows and numerical integrators.},
1840	+	annote = {Zc449 Times Cited:14 Cited References Count:33},
1841	+	issn = {0036-1429},
1842	+	uri = {<Go to ISI>://000072580500010},
1843	+	}
1844	+
1845		@ARTICLE{McLachlan2005,
1846		author = {R. I. McLachlan and A. Zanna},
1847		title = {The discrete Moser-Veselov algorithm for the free rigid body, revisited},
#	Line 1505 | Line 1852 | Encoding: GBK
1852		number = {1},
1853		month = {Feb},
1854		abstract = {In this paper we revisit the Moser-Veselov description of the free
1855	<	rigid body in body coordinates, which, in the 3 x 3 case, can be
1856	<	implemented as an explicit, second-order, integrable approximation
1857	<	of the continuous solution. By backward error analysis, we study
1858	<	the modified vector field which is integrated exactly by the discrete
1859	<	algorithm. We deduce that the discrete Moser-Veselov (DMV) is well
1860	<	approximated to higher order by time reparametrizations of the continuous
1861	<	equations (modified vector field). We use the modified vector field
1862	<	to scale the initial data of the DMV to improve the order of the
1863	<	approximation and show the equivalence of the DMV and the RATTLE
1864	<	algorithm. Numerical integration with these preprocessed initial
1865	<	data is several orders of magnitude more accurate than the original
1866	<	DMV and RATTLE approach.},
1855	>	rigid body in body coordinates, which, in the 3 x 3 case, can be
1856	>	implemented as an explicit, second-order, integrable approximation
1857	>	of the continuous solution. By backward error analysis, we study
1858	>	the modified vector field which is integrated exactly by the discrete
1859	>	algorithm. We deduce that the discrete Moser-Veselov (DMV) is well
1860	>	approximated to higher order by time reparametrizations of the continuous
1861	>	equations (modified vector field). We use the modified vector field
1862	>	to scale the initial data of the DMV to improve the order of the
1863	>	approximation and show the equivalence of the DMV and the RATTLE
1864	>	algorithm. Numerical integration with these preprocessed initial
1865	>	data is several orders of magnitude more accurate than the original
1866	>	DMV and RATTLE approach.},
1867		annote = {911NS Times Cited:0 Cited References Count:14},
1868		issn = {1615-3375},
1869		uri = {<Go to ISI>://000228011900003},
#	Line 1525 | Line 1872 | Encoding: GBK
1872		@ARTICLE{Memmer2002,
1873		author = {R. Memmer},
1874		title = {Liquid crystal phases of achiral banana-shaped molecules: a computer
1875	<	simulation study},
1875	>	simulation study},
1876		journal = {Liquid Crystals},
1877		year = {2002},
1878		volume = {29},
#	Line 1533 | Line 1880 | Encoding: GBK
1880		number = {4},
1881		month = {Apr},
1882		abstract = {The phase behaviour of achiral banana-shaped molecules was studied
1883	<	by computer simulation. The banana-shaped molecules were described
1884	<	by model intermolecular interactions based on the Gay-Berne potential.
1885	<	The characteristic molecular structure was considered by joining
1886	<	two calamitic Gay-Berne particles through a bond to form a biaxial
1887	<	molecule of point symmetry group C-2v with a suitable bending angle.
1888	<	The dependence on temperature of systems of N=1024 rigid banana-shaped
1889	<	molecules with bending angle phi=140degrees has been studied by
1890	<	means of Monte Carlo simulations in the isobaric-isothermal ensemble
1891	<	(NpT). On cooling an isotropic system, two phase transitions characterized
1892	<	by phase transition enthalpy, entropy and relative volume change
1893	<	have been observed. For the first time by computer simulation of
1894	<	a many-particle system of banana-shaped molecules, at low temperature
1895	<	an untilted smectic phase showing a global phase biaxiality and
1896	<	a spontaneous local polarization in the layers, i.e. a local polar
1897	<	arrangement of the steric dipoles, with an antiferroelectric-like
1898	<	superstructure could be proven, a phase structure which recently
1899	<	has been discovered experimentally. Additionally, at intermediate
1900	<	temperature a nematic-like phase has been proved, whereas close
1901	<	to the transition to the smectic phase hints of a spontaneous achiral
1902	<	symmetry breaking have been determined. Here, in the absence of
1903	<	a layered structure a helical superstructure has been formed. All
1904	<	phases have been characterized by visual representations of selected
1905	<	configurations, scalar and pseudoscalar correlation functions, and
1906	<	order parameters.},
1883	>	by computer simulation. The banana-shaped molecules were described
1884	>	by model intermolecular interactions based on the Gay-Berne potential.
1885	>	The characteristic molecular structure was considered by joining
1886	>	two calamitic Gay-Berne particles through a bond to form a biaxial
1887	>	molecule of point symmetry group C-2v with a suitable bending angle.
1888	>	The dependence on temperature of systems of N=1024 rigid banana-shaped
1889	>	molecules with bending angle phi=140degrees has been studied by
1890	>	means of Monte Carlo simulations in the isobaric-isothermal ensemble
1891	>	(NpT). On cooling an isotropic system, two phase transitions characterized
1892	>	by phase transition enthalpy, entropy and relative volume change
1893	>	have been observed. For the first time by computer simulation of
1894	>	a many-particle system of banana-shaped molecules, at low temperature
1895	>	an untilted smectic phase showing a global phase biaxiality and
1896	>	a spontaneous local polarization in the layers, i.e. a local polar
1897	>	arrangement of the steric dipoles, with an antiferroelectric-like
1898	>	superstructure could be proven, a phase structure which recently
1899	>	has been discovered experimentally. Additionally, at intermediate
1900	>	temperature a nematic-like phase has been proved, whereas close
1901	>	to the transition to the smectic phase hints of a spontaneous achiral
1902	>	symmetry breaking have been determined. Here, in the absence of
1903	>	a layered structure a helical superstructure has been formed. All
1904	>	phases have been characterized by visual representations of selected
1905	>	configurations, scalar and pseudoscalar correlation functions, and
1906	>	order parameters.},
1907		annote = {531HT Times Cited:12 Cited References Count:37},
1908		issn = {0267-8292},
1909		uri = {<Go to ISI>://000174410500001},
#	Line 1573 | Line 1920 | Encoding: GBK
1920
1921		@ARTICLE{Mielke2004,
1922		author = {S. P. Mielke and W. H. Fink and V. V. Krishnan and N. Gronbech-Jensen
1923	<	and C. J. Benham},
1923	>	and C. J. Benham},
1924		title = {Transcription-driven twin supercoiling of a DNA loop: A Brownian
1925	<	dynamics study},
1925	>	dynamics study},
1926		journal = {Journal of Chemical Physics},
1927		year = {2004},
1928		volume = {121},
#	Line 1583 | Line 1930 | Encoding: GBK
1930		number = {16},
1931		month = {Oct 22},
1932		abstract = {The torque generated by RNA polymerase as it tracks along double-stranded
1933	<	DNA can potentially induce long-range structural deformations integral
1934	<	to mechanisms of biological significance in both prokaryotes and
1935	<	eukaryotes. In this paper, we introduce a dynamic computer model
1936	<	for investigating this phenomenon. Duplex DNA is represented as
1937	<	a chain of hydrodynamic beads interacting through potentials of
1938	<	linearly elastic stretching, bending, and twisting, as well as excluded
1939	<	volume. The chain, linear when relaxed, is looped to form two open
1940	<	but topologically constrained subdomains. This permits the dynamic
1941	<	introduction of torsional stress via a centrally applied torque.
1942	<	We simulate by Brownian dynamics the 100 mus response of a 477-base
1943	<	pair B-DNA template to the localized torque generated by the prokaryotic
1944	<	transcription ensemble. Following a sharp rise at early times, the
1945	<	distributed twist assumes a nearly constant value in both subdomains,
1946	<	and a succession of supercoiling deformations occurs as superhelical
1947	<	stress is increasingly partitioned to writhe. The magnitude of writhe
1948	<	surpasses that of twist before also leveling off when the structure
1949	<	reaches mechanical equilibrium with the torsional load. Superhelicity
1950	<	is simultaneously right handed in one subdomain and left handed
1951	<	in the other, as predicted by the #transcription-induced##twin-supercoiled-domain#
1952	<	model [L. F. Liu and J. C. Wang, Proc. Natl. Acad. Sci. U.S.A. 84,
1953	<	7024 (1987)]. The properties of the chain at the onset of writhing
1954	<	agree well with predictions from theory, and the generated stress
1955	<	is ample for driving secondary structural transitions in physiological
1956	<	DNA. (C) 2004 American Institute of Physics.},
1933	>	DNA can potentially induce long-range structural deformations integral
1934	>	to mechanisms of biological significance in both prokaryotes and
1935	>	eukaryotes. In this paper, we introduce a dynamic computer model
1936	>	for investigating this phenomenon. Duplex DNA is represented as
1937	>	a chain of hydrodynamic beads interacting through potentials of
1938	>	linearly elastic stretching, bending, and twisting, as well as excluded
1939	>	volume. The chain, linear when relaxed, is looped to form two open
1940	>	but topologically constrained subdomains. This permits the dynamic
1941	>	introduction of torsional stress via a centrally applied torque.
1942	>	We simulate by Brownian dynamics the 100 mus response of a 477-base
1943	>	pair B-DNA template to the localized torque generated by the prokaryotic
1944	>	transcription ensemble. Following a sharp rise at early times, the
1945	>	distributed twist assumes a nearly constant value in both subdomains,
1946	>	and a succession of supercoiling deformations occurs as superhelical
1947	>	stress is increasingly partitioned to writhe. The magnitude of writhe
1948	>	surpasses that of twist before also leveling off when the structure
1949	>	reaches mechanical equilibrium with the torsional load. Superhelicity
1950	>	is simultaneously right handed in one subdomain and left handed
1951	>	in the other, as predicted by the #transcription-induced##twin-supercoiled-domain#
1952	>	model [L. F. Liu and J. C. Wang, Proc. Natl. Acad. Sci. U.S.A. 84,
1953	>	7024 (1987)]. The properties of the chain at the onset of writhing
1954	>	agree well with predictions from theory, and the generated stress
1955	>	is ample for driving secondary structural transitions in physiological
1956	>	DNA. (C) 2004 American Institute of Physics.},
1957		annote = {861ZF Times Cited:3 Cited References Count:34},
1958		issn = {0021-9606},
1959		uri = {<Go to ISI>://000224456500064},
#	Line 1615 | Line 1962 | Encoding: GBK
1962		@ARTICLE{Naess2001,
1963		author = {S. N. Naess and H. M. Adland and A. Mikkelsen and A. Elgsaeter},
1964		title = {Brownian dynamics simulation of rigid bodies and segmented polymer
1965	<	chains. Use of Cartesian rotation vectors as the generalized coordinates
1966	<	describing angular orientations},
1965	>	chains. Use of Cartesian rotation vectors as the generalized coordinates
1966	>	describing angular orientations},
1967		journal = {Physica A},
1968		year = {2001},
1969		volume = {294},
#	Line 1624 | Line 1971 | Encoding: GBK
1971		number = {3-4},
1972		month = {May 15},
1973		abstract = {The three Eulerian angles constitute the classical choice of generalized
1974	<	coordinates used to describe the three degrees of rotational freedom
1975	<	of a rigid body, but it has long been known that this choice yields
1976	<	singular equations of motion. The latter is also true when Eulerian
1977	<	angles are used in Brownian dynamics analyses of the angular orientation
1978	<	of single rigid bodies and segmented polymer chains. Starting from
1979	<	kinetic theory we here show that by instead employing the three
1980	<	components of Cartesian rotation vectors as the generalized coordinates
1981	<	describing angular orientation, no singularity appears in the configuration
1982	<	space diffusion equation and the associated Brownian dynamics algorithm.
1983	<	The suitability of Cartesian rotation vectors in Brownian dynamics
1984	<	simulations of segmented polymer chains with spring-like or ball-socket
1985	<	joints is discussed. (C) 2001 Elsevier Science B.V. All rights reserved.},
1974	>	coordinates used to describe the three degrees of rotational freedom
1975	>	of a rigid body, but it has long been known that this choice yields
1976	>	singular equations of motion. The latter is also true when Eulerian
1977	>	angles are used in Brownian dynamics analyses of the angular orientation
1978	>	of single rigid bodies and segmented polymer chains. Starting from
1979	>	kinetic theory we here show that by instead employing the three
1980	>	components of Cartesian rotation vectors as the generalized coordinates
1981	>	describing angular orientation, no singularity appears in the configuration
1982	>	space diffusion equation and the associated Brownian dynamics algorithm.
1983	>	The suitability of Cartesian rotation vectors in Brownian dynamics
1984	>	simulations of segmented polymer chains with spring-like or ball-socket
1985	>	joints is discussed. (C) 2001 Elsevier Science B.V. All rights reserved.},
1986		annote = {433TA Times Cited:7 Cited References Count:19},
1987		issn = {0378-4371},
1988		uri = {<Go to ISI>://000168774800005},
#	Line 1644 | Line 1991 | Encoding: GBK
1991		@ARTICLE{Niori1996,
1992		author = {T. Niori and T. Sekine and J. Watanabe and T. Furukawa and H. Takezoe},
1993		title = {Distinct ferroelectric smectic liquid crystals consisting of banana
1994	<	shaped achiral molecules},
1994	>	shaped achiral molecules},
1995		journal = {Journal of Materials Chemistry},
1996		year = {1996},
1997		volume = {6},
#	Line 1652 | Line 1999 | Encoding: GBK
1999		number = {7},
2000		month = {Jul},
2001		abstract = {The synthesis of a banana-shaped molecule is reported and it is found
2002	<	that the smectic phase which it forms is biaxial with the molecules
2003	<	packed in the best,direction into a layer. Because of this characteristic
2004	<	packing, spontaneous polarization appears parallel to the layer
2005	<	and switches on reversal of an applied electric field. This is the
2006	<	first obvious example of ferroelectricity in an achiral smectic
2007	<	phase and is ascribed to the C-2v symmetry of the molecular packing.},
2002	>	that the smectic phase which it forms is biaxial with the molecules
2003	>	packed in the best,direction into a layer. Because of this characteristic
2004	>	packing, spontaneous polarization appears parallel to the layer
2005	>	and switches on reversal of an applied electric field. This is the
2006	>	first obvious example of ferroelectricity in an achiral smectic
2007	>	phase and is ascribed to the C-2v symmetry of the molecular packing.},
2008		annote = {Ux855 Times Cited:447 Cited References Count:18},
2009		issn = {0959-9428},
2010		uri = {<Go to ISI>://A1996UX85500025},
#	Line 1673 | Line 2020 | Encoding: GBK
2020		number = {5},
2021		month = {may},
2022		abstract = {We Studied the structural changes of bilayer vesicles induced by mechanical
2023	<	forces using a Brownian dynamics simulation. Two nanoparticles,
2024	<	which interact repulsively with amphiphilic molecules, are put inside
2025	<	a vesicle. The position of one nanoparticle is fixed, and the other
2026	<	is moved by a constant force as in optical-trapping experiments.
2027	<	First, the pulled vesicle stretches into a pear or tube shape. Then
2028	<	the inner monolayer in the tube-shaped region is deformed, and a
2029	<	cylindrical structure is formed between two vesicles. After stretching
2030	<	the cylindrical region, fission occurs near the moved vesicle. Soon
2031	<	after this the cylindrical region shrinks. The trapping force similar
2032	<	to 100 pN is needed to induce the formation of the cylindrical structure
2033	<	and fission.},
2023	>	forces using a Brownian dynamics simulation. Two nanoparticles,
2024	>	which interact repulsively with amphiphilic molecules, are put inside
2025	>	a vesicle. The position of one nanoparticle is fixed, and the other
2026	>	is moved by a constant force as in optical-trapping experiments.
2027	>	First, the pulled vesicle stretches into a pear or tube shape. Then
2028	>	the inner monolayer in the tube-shaped region is deformed, and a
2029	>	cylindrical structure is formed between two vesicles. After stretching
2030	>	the cylindrical region, fission occurs near the moved vesicle. Soon
2031	>	after this the cylindrical region shrinks. The trapping force similar
2032	>	to 100 pN is needed to induce the formation of the cylindrical structure
2033	>	and fission.},
2034		annote = {Part 1 568PX Times Cited:5 Cited References Count:39},
2035		issn = {1063-651X},
2036		uri = {<Go to ISI>://000176552300084},
#	Line 1699 | Line 2046 | Encoding: GBK
2046		number = {20},
2047		month = {Nov 22},
2048		abstract = {We studied the fusion dynamics of vesicles using a Brownian dynamics
2049	<	simulation. Amphiphilic molecules spontaneously form vesicles with
2050	<	a bilayer structure. Two vesicles come into contact and form a stalk
2051	<	intermediate, in which a necklike structure only connects the outer
2052	<	monolayers, as predicted by the stalk hypothesis. We have found
2053	<	a new pathway of pore opening from stalks at high temperature: the
2054	<	elliptic stalk bends and contact between the ends of the arc-shaped
2055	<	stalk leads to pore opening. On the other hand, we have clarified
2056	<	that the pore-opening process at low temperature agrees with the
2057	<	modified stalk model: a pore is induced by contact between the inner
2058	<	monolayers inside the stalk. (C) 2001 American Institute of Physics.},
2049	>	simulation. Amphiphilic molecules spontaneously form vesicles with
2050	>	a bilayer structure. Two vesicles come into contact and form a stalk
2051	>	intermediate, in which a necklike structure only connects the outer
2052	>	monolayers, as predicted by the stalk hypothesis. We have found
2053	>	a new pathway of pore opening from stalks at high temperature: the
2054	>	elliptic stalk bends and contact between the ends of the arc-shaped
2055	>	stalk leads to pore opening. On the other hand, we have clarified
2056	>	that the pore-opening process at low temperature agrees with the
2057	>	modified stalk model: a pore is induced by contact between the inner
2058	>	monolayers inside the stalk. (C) 2001 American Institute of Physics.},
2059		annote = {491UW Times Cited:48 Cited References Count:25},
2060		issn = {0021-9606},
2061		uri = {<Go to ISI>://000172129300049},
2062		}
2063
2064	+	@BOOK{Olver1986,
2065	+	title = {Applications of Lie groups to differential equatitons},
2066	+	publisher = {Springer},
2067	+	year = {1986},
2068	+	author = {P.J. Olver},
2069	+	address = {New York},
2070	+	}
2071	+
2072	+	@ARTICLE{Omelyan1998,
2073	+	author = {I. P. Omelyan},
2074	+	title = {On the numerical integration of motion for rigid polyatomics: The
2075	+	modified quaternion approach},
2076	+	journal = {Computers in Physics},
2077	+	year = {1998},
2078	+	volume = {12},
2079	+	pages = {97-103},
2080	+	number = {1},
2081	+	month = {Jan-Feb},
2082	+	abstract = {A revised version of the quaternion approach for numerical integration
2083	+	of the equations of motion for rigid polyatomic molecules is proposed.
2084	+	The modified approach is based on a formulation of the quaternion
2085	+	dynamics with constraints. This allows one to resolve the rigidity
2086	+	problem rigorously using constraint forces. It is shown that the
2087	+	procedure for preservation of molecular rigidity can be realized
2088	+	particularly simply within the Verlet algorithm in velocity form.
2089	+	We demonstrate that the method presented leads to an improved numerical
2090	+	stability with respect to the usual quaternion rescaling scheme
2091	+	and it is roughly as good as the cumbersome atomic-constraint technique.
2092	+	(C) 1998 American Institute of Physics.},
2093	+	annote = {Yx279 Times Cited:12 Cited References Count:28},
2094	+	issn = {0894-1866},
2095	+	uri = {<Go to ISI>://000072024300025},
2096	+	}
2097	+
2098	+	@ARTICLE{Omelyan1998a,
2099	+	author = {I. P. Omelyan},
2100	+	title = {Algorithm for numerical integration of the rigid-body equations of
2101	+	motion},
2102	+	journal = {Physical Review E},
2103	+	year = {1998},
2104	+	volume = {58},
2105	+	pages = {1169-1172},
2106	+	number = {1},
2107	+	month = {Jul},
2108	+	abstract = {An algorithm for numerical integration of the rigid-body equations
2109	+	of motion is proposed. The algorithm uses the leapfrog scheme and
2110	+	the quantities involved are angular velocities and orientational
2111	+	variables that can be expressed in terms of either principal axes
2112	+	or quaternions. Due to specific features of the algorithm, orthonormality
2113	+	and unit norms of the orientational variables are integrals of motion,
2114	+	despite an approximate character of the produced trajectories. It
2115	+	is shown that the method presented appears to be the most efficient
2116	+	among all such algorithms known.},
2117	+	annote = {101XL Times Cited:8 Cited References Count:22},
2118	+	issn = {1063-651X},
2119	+	uri = {<Go to ISI>://000074893400151},
2120	+	}
2121	+
2122		@ARTICLE{Orlandi2006,
2123		author = {S. Orlandi and R. Berardi and J. Steltzer and C. Zannoni},
2124		title = {A Monte Carlo study of the mesophases formed by polar bent-shaped
2125	<	molecules},
2125	>	molecules},
2126		journal = {Journal of Chemical Physics},
2127		year = {2006},
2128		volume = {124},
#	Line 1725 | Line 2130 | Encoding: GBK
2130		number = {12},
2131		month = {Mar 28},
2132		abstract = {Liquid crystal phases formed by bent-shaped (or #banana#) molecules
2133	<	are currently of great interest. Here we investigate by Monte Carlo
2134	<	computer simulations the phases formed by rigid banana molecules
2135	<	modeled combining three Gay-Berne sites and containing either one
2136	<	central or two lateral and transversal dipoles. We show that changing
2137	<	the dipole position and orientation has a profound effect on the
2138	<	mesophase stability and molecular organization. In particular, we
2139	<	find a uniaxial nematic phase only for off-center dipolar models
2140	<	and tilted phases only for the one with terminal dipoles. (c) 2006
2141	<	American Institute of Physics.},
2133	>	are currently of great interest. Here we investigate by Monte Carlo
2134	>	computer simulations the phases formed by rigid banana molecules
2135	>	modeled combining three Gay-Berne sites and containing either one
2136	>	central or two lateral and transversal dipoles. We show that changing
2137	>	the dipole position and orientation has a profound effect on the
2138	>	mesophase stability and molecular organization. In particular, we
2139	>	find a uniaxial nematic phase only for off-center dipolar models
2140	>	and tilted phases only for the one with terminal dipoles. (c) 2006
2141	>	American Institute of Physics.},
2142		annote = {028CP Times Cited:0 Cited References Count:42},
2143		issn = {0021-9606},
2144		uri = {<Go to ISI>://000236464000072},
2145		}
2146
2147	+	@ARTICLE{Owren1992,
2148	+	author = {B. Owren and M. Zennaro},
2149	+	title = {Derivation of Efficient, Continuous, Explicit Runge-Kutta Methods},
2150	+	journal = {Siam Journal on Scientific and Statistical Computing},
2151	+	year = {1992},
2152	+	volume = {13},
2153	+	pages = {1488-1501},
2154	+	number = {6},
2155	+	month = {Nov},
2156	+	abstract = {Continuous, explicit Runge-Kutta methods with the minimal number of
2157	+	stages are considered. These methods are continuously differentiable
2158	+	if and only if one of the stages is the FSAL evaluation. A characterization
2159	+	of a subclass of these methods is developed for orders 3, 4, and
2160	+	5. It is shown how the free parameters of these methods can be used
2161	+	either to minimize the continuous truncation error coefficients
2162	+	or to maximize the stability region. As a representative for these
2163	+	methods the fifth-order method with minimized error coefficients
2164	+	is chosen, supplied with an error estimation method, and analysed
2165	+	by using the DETEST software. The results are compared with a similar
2166	+	implementation of the Dormand-Prince 5(4) pair with interpolant,
2167	+	showing a significant advantage in the new method for the chosen
2168	+	problems.},
2169	+	annote = {Ju936 Times Cited:25 Cited References Count:20},
2170	+	issn = {0196-5204},
2171	+	uri = {<Go to ISI>://A1992JU93600013},
2172	+	}
2173	+
2174		@ARTICLE{Palacios1998,
2175		author = {J. L. Garcia-Palacios and F. J. Lazaro},
2176		title = {Langevin-dynamics study of the dynamical properties of small magnetic
2177	<	particles},
2177	>	particles},
2178		journal = {Physical Review B},
2179		year = {1998},
2180		volume = {58},
#	Line 1750 | Line 2182 | Encoding: GBK
2182		number = {22},
2183		month = {Dec 1},
2184		abstract = {The stochastic Landau-Lifshitz-Gilbert equation of motion for a classical
2185	<	magnetic moment is numerically solved (properly observing the customary
2186	<	interpretation of it as a Stratonovich stochastic differential equation),
2187	<	in order to study the dynamics of magnetic nanoparticles. The corresponding
2188	<	Langevin-dynamics approach allows for the study of the fluctuating
2189	<	trajectories of individual magnetic moments, where we have encountered
2190	<	remarkable phenomena in the overbarrier rotation process, such as
2191	<	crossing-back or multiple crossing of the potential barrier, rooted
2192	<	in the gyromagnetic nature of the system. Concerning averaged quantities,
2193	<	we study the linear dynamic response of the archetypal ensemble
2194	<	of noninteracting classical magnetic moments with axially symmetric
2195	<	magnetic anisotropy. The results are compared with different analytical
2196	<	expressions used to model the relaxation of nanoparticle ensembles,
2197	<	assessing their accuracy. It has been found that, among a number
2198	<	of heuristic expressions for the linear dynamic susceptibility,
2199	<	only the simple formula proposed by Shliomis and Stepanov matches
2200	<	the coarse features of the susceptibility reasonably. By comparing
2201	<	the numerical results with the asymptotic formula of Storonkin {Sov.
2202	<	Phys. Crystallogr. 30, 489 (1985) [Kristallografiya 30, 841 (1985)]},
2203	<	the effects of the intra-potential-well relaxation modes on the
2204	<	low-temperature longitudinal dynamic response have been assessed,
2205	<	showing their relatively small reflection in the susceptibility
2206	<	curves but their dramatic influence on the phase shifts. Comparison
2207	<	of the numerical results with the exact zero-damping expression
2208	<	for the transverse susceptibility by Garanin, Ishchenko, and Panina
2209	<	{Theor. Math. Phys. (USSR) 82, 169 (1990) [Teor. Mat. Fit. 82, 242
2210	<	(1990)]}, reveals a sizable contribution of the spread of the precession
2211	<	frequencies of the magnetic moment in the anisotropy field to the
2212	<	dynamic response at intermediate-to-high temperatures. [S0163-1829
2213	<	(98)00446-9].},
2185	>	magnetic moment is numerically solved (properly observing the customary
2186	>	interpretation of it as a Stratonovich stochastic differential equation),
2187	>	in order to study the dynamics of magnetic nanoparticles. The corresponding
2188	>	Langevin-dynamics approach allows for the study of the fluctuating
2189	>	trajectories of individual magnetic moments, where we have encountered
2190	>	remarkable phenomena in the overbarrier rotation process, such as
2191	>	crossing-back or multiple crossing of the potential barrier, rooted
2192	>	in the gyromagnetic nature of the system. Concerning averaged quantities,
2193	>	we study the linear dynamic response of the archetypal ensemble
2194	>	of noninteracting classical magnetic moments with axially symmetric
2195	>	magnetic anisotropy. The results are compared with different analytical
2196	>	expressions used to model the relaxation of nanoparticle ensembles,
2197	>	assessing their accuracy. It has been found that, among a number
2198	>	of heuristic expressions for the linear dynamic susceptibility,
2199	>	only the simple formula proposed by Shliomis and Stepanov matches
2200	>	the coarse features of the susceptibility reasonably. By comparing
2201	>	the numerical results with the asymptotic formula of Storonkin {Sov.
2202	>	Phys. Crystallogr. 30, 489 (1985) [Kristallografiya 30, 841 (1985)]},
2203	>	the effects of the intra-potential-well relaxation modes on the
2204	>	low-temperature longitudinal dynamic response have been assessed,
2205	>	showing their relatively small reflection in the susceptibility
2206	>	curves but their dramatic influence on the phase shifts. Comparison
2207	>	of the numerical results with the exact zero-damping expression
2208	>	for the transverse susceptibility by Garanin, Ishchenko, and Panina
2209	>	{Theor. Math. Phys. (USSR) 82, 169 (1990) [Teor. Mat. Fit. 82, 242
2210	>	(1990)]}, reveals a sizable contribution of the spread of the precession
2211	>	frequencies of the magnetic moment in the anisotropy field to the
2212	>	dynamic response at intermediate-to-high temperatures. [S0163-1829
2213	>	(98)00446-9].},
2214		annote = {146XW Times Cited:66 Cited References Count:45},
2215		issn = {0163-1829},
2216		uri = {<Go to ISI>://000077460000052},
#	Line 1815 | Line 2247 | Encoding: GBK
2247		@ARTICLE{Perram1985,
2248		author = {J. W. Perram and M. S. Wertheim},
2249		title = {Statistical-Mechanics of Hard Ellipsoids .1. Overlap Algorithm and
2250	<	the Contact Function},
2250	>	the Contact Function},
2251		journal = {Journal of Computational Physics},
2252		year = {1985},
2253		volume = {58},
#	Line 1826 | Line 2258 | Encoding: GBK
2258		uri = {<Go to ISI>://A1985AKB9300008},
2259		}
2260
2261	+	@ARTICLE{Rotne1969,
2262	+	author = {F. Perrin},
2263	+	title = {Variational treatment of hydrodynamic interaction in polymers},
2264	+	journal = {J. Chem. Phys.},
2265	+	year = {1969},
2266	+	volume = {50},
2267	+	pages = {4831¨C4837},
2268	+	}
2269	+
2270	+	@ARTICLE{Perrin1936,
2271	+	author = {F. Perrin},
2272	+	title = {Mouvement brownien d'un ellipsoid(II). Rotation libre et depolarisation
2273	+	des fluorescences. Translation et diffusion de moleculese ellipsoidales},
2274	+	journal = {J. Phys. Radium},
2275	+	year = {1936},
2276	+	volume = {7},
2277	+	pages = {1-11},
2278	+	}
2279	+
2280	+	@ARTICLE{Perrin1934,
2281	+	author = {F. Perrin},
2282	+	title = {Mouvement brownien d'un ellipsoid(I). Dispersion dielectrique pour
2283	+	des molecules ellipsoidales},
2284	+	journal = {J. Phys. Radium},
2285	+	year = {1934},
2286	+	volume = {5},
2287	+	pages = {497-511},
2288	+	}
2289	+
2290		@ARTICLE{Petrache1998,
2291		author = {H. I. Petrache and S. Tristram-Nagle and J. F. Nagle},
2292		title = {Fluid phase structure of EPC and DMPC bilayers},
#	Line 1836 | Line 2297 | Encoding: GBK
2297		number = {1},
2298		month = {Sep},
2299		abstract = {X-ray diffraction data taken at high instrumental resolution were
2300	<	obtained for EPC and DMPC under various osmotic pressures, primarily
2301	<	at T = 30 degrees C. The headgroup thickness D-HH was obtained from
2302	<	relative electron density profiles. By using volumetric results
2303	<	and by comparing to gel phase DPPC we obtain areas A(EPC)(F) = 69.4
2304	<	+/- 1.1 Angstrom(2) and A(DMPC)(F) = 59.7 +/- 0.2 Angstrom(2). The
2305	<	analysis also gives estimates for the areal compressibility K-A.
2306	<	The A(F) results lead to other structural results regarding membrane
2307	<	thickness and associated waters. Using the recently determined absolute
2308	<	electrons density profile of DPPC, the AF results also lead to absolute
2309	<	electron density profiles and absolute continuous transforms \F(q)\
2310	<	for EPC and DMPC, Limited measurements of temperature dependence
2311	<	show directly that fluctuations increase with increasing temperature
2312	<	and that a small decrease in bending modulus K-c accounts for the
2313	<	increased water spacing reported by Simon et al. (1995) Biophys.
2314	<	J. 69, 1473-1483. (C) 1998 Elsevier Science Ireland Ltd. All rights
2315	<	reserved.},
2300	>	obtained for EPC and DMPC under various osmotic pressures, primarily
2301	>	at T = 30 degrees C. The headgroup thickness D-HH was obtained from
2302	>	relative electron density profiles. By using volumetric results
2303	>	and by comparing to gel phase DPPC we obtain areas A(EPC)(F) = 69.4
2304	>	+/- 1.1 Angstrom(2) and A(DMPC)(F) = 59.7 +/- 0.2 Angstrom(2). The
2305	>	analysis also gives estimates for the areal compressibility K-A.
2306	>	The A(F) results lead to other structural results regarding membrane
2307	>	thickness and associated waters. Using the recently determined absolute
2308	>	electrons density profile of DPPC, the AF results also lead to absolute
2309	>	electron density profiles and absolute continuous transforms \F(q)\
2310	>	for EPC and DMPC, Limited measurements of temperature dependence
2311	>	show directly that fluctuations increase with increasing temperature
2312	>	and that a small decrease in bending modulus K-c accounts for the
2313	>	increased water spacing reported by Simon et al. (1995) Biophys.
2314	>	J. 69, 1473-1483. (C) 1998 Elsevier Science Ireland Ltd. All rights
2315	>	reserved.},
2316		annote = {130AT Times Cited:98 Cited References Count:39},
2317		issn = {0009-3084},
2318		uri = {<Go to ISI>://000076497600007},
#	Line 1860 | Line 2321 | Encoding: GBK
2321		@ARTICLE{Powles1973,
2322		author = {J.~G. Powles},
2323		title = {A general ellipsoid can not always serve as a modle for the rotational
2324	<	diffusion properties of arbitrary shaped rigid molecules},
2324	>	diffusion properties of arbitrary shaped rigid molecules},
2325		journal = {Advan. Phys.},
2326		year = {1973},
2327		volume = {22},
#	Line 1870 | Line 2331 | Encoding: GBK
2331		@ARTICLE{Recio2004,
2332		author = {J. Fernandez-Recio and M. Totrov and R. Abagyan},
2333		title = {Identification of protein-protein interaction sites from docking
2334	<	energy landscapes},
2334	>	energy landscapes},
2335		journal = {Journal of Molecular Biology},
2336		year = {2004},
2337		volume = {335},
#	Line 1878 | Line 2339 | Encoding: GBK
2339		number = {3},
2340		month = {Jan 16},
2341		abstract = {Protein recognition is one of the most challenging and intriguing
2342	<	problems in structural biology. Despite all the available structural,
2343	<	sequence and biophysical information about protein-protein complexes,
2344	<	the physico-chemical patterns, if any, that make a protein surface
2345	<	likely to be involved in protein-protein interactions, remain elusive.
2346	<	Here, we apply protein docking simulations and analysis of the interaction
2347	<	energy landscapes to identify protein-protein interaction sites.
2348	<	The new protocol for global docking based on multi-start global
2349	<	energy optimization of an allatom model of the ligand, with detailed
2350	<	receptor potentials and atomic solvation parameters optimized in
2351	<	a training set of 24 complexes, explores the conformational space
2352	<	around the whole receptor without restrictions. The ensembles of
2353	<	the rigid-body docking solutions generated by the simulations were
2354	<	subsequently used to project the docking energy landscapes onto
2355	<	the protein surfaces. We found that highly populated low-energy
2356	<	regions consistently corresponded to actual binding sites. The procedure
2357	<	was validated on a test set of 21 known protein-protein complexes
2358	<	not used in the training set. As much as 81% of the predicted high-propensity
2359	<	patch residues were located correctly in the native interfaces.
2360	<	This approach can guide the design of mutations on the surfaces
2361	<	of proteins, provide geometrical details of a possible interaction,
2362	<	and help to annotate protein surfaces in structural proteomics.
2363	<	(C) 2003 Elsevier Ltd. All rights reserved.},
2342	>	problems in structural biology. Despite all the available structural,
2343	>	sequence and biophysical information about protein-protein complexes,
2344	>	the physico-chemical patterns, if any, that make a protein surface
2345	>	likely to be involved in protein-protein interactions, remain elusive.
2346	>	Here, we apply protein docking simulations and analysis of the interaction
2347	>	energy landscapes to identify protein-protein interaction sites.
2348	>	The new protocol for global docking based on multi-start global
2349	>	energy optimization of an allatom model of the ligand, with detailed
2350	>	receptor potentials and atomic solvation parameters optimized in
2351	>	a training set of 24 complexes, explores the conformational space
2352	>	around the whole receptor without restrictions. The ensembles of
2353	>	the rigid-body docking solutions generated by the simulations were
2354	>	subsequently used to project the docking energy landscapes onto
2355	>	the protein surfaces. We found that highly populated low-energy
2356	>	regions consistently corresponded to actual binding sites. The procedure
2357	>	was validated on a test set of 21 known protein-protein complexes
2358	>	not used in the training set. As much as 81% of the predicted high-propensity
2359	>	patch residues were located correctly in the native interfaces.
2360	>	This approach can guide the design of mutations on the surfaces
2361	>	of proteins, provide geometrical details of a possible interaction,
2362	>	and help to annotate protein surfaces in structural proteomics.
2363	>	(C) 2003 Elsevier Ltd. All rights reserved.},
2364		annote = {763GQ Times Cited:21 Cited References Count:59},
2365		issn = {0022-2836},
2366		uri = {<Go to ISI>://000188066900016},
#	Line 1908 | Line 2369 | Encoding: GBK
2369		@ARTICLE{Reddy2006,
2370		author = {R. A. Reddy and C. Tschierske},
2371		title = {Bent-core liquid crystals: polar order, superstructural chirality
2372	<	and spontaneous desymmetrisation in soft matter systems},
2372	>	and spontaneous desymmetrisation in soft matter systems},
2373		journal = {Journal of Materials Chemistry},
2374		year = {2006},
2375		volume = {16},
2376		pages = {907-961},
2377		number = {10},
2378		abstract = {An overview on the recent developments in the field of liquid crystalline
2379	<	bent-core molecules (so-called banana liquid crystals) is given.
2380	<	After some basic issues, dealing with general aspects of the systematisation
2381	<	of the mesophases, development of polar order and chirality in this
2382	<	class of LC systems and explaining some general structure-property
2383	<	relationships, we focus on fascinating new developments in this
2384	<	field, such as modulated, undulated and columnar phases, so-called
2385	<	B7 phases, phase biaxiality, ferroelectric and antiferroelectric
2386	<	polar order in smectic and columnar phases, amplification and switching
2387	<	of chirality and the spontaneous formation of superstructural and
2388	<	supramolecular chirality.},
2379	>	bent-core molecules (so-called banana liquid crystals) is given.
2380	>	After some basic issues, dealing with general aspects of the systematisation
2381	>	of the mesophases, development of polar order and chirality in this
2382	>	class of LC systems and explaining some general structure-property
2383	>	relationships, we focus on fascinating new developments in this
2384	>	field, such as modulated, undulated and columnar phases, so-called
2385	>	B7 phases, phase biaxiality, ferroelectric and antiferroelectric
2386	>	polar order in smectic and columnar phases, amplification and switching
2387	>	of chirality and the spontaneous formation of superstructural and
2388	>	supramolecular chirality.},
2389		annote = {021NS Times Cited:2 Cited References Count:316},
2390		issn = {0959-9428},
2391		uri = {<Go to ISI>://000235990500001},
2392		}
2393
2394	+	@ARTICLE{Reich1999,
2395	+	author = {S. Reich},
2396	+	title = {Backward error analysis for numerical integrators},
2397	+	journal = {Siam Journal on Numerical Analysis},
2398	+	year = {1999},
2399	+	volume = {36},
2400	+	pages = {1549-1570},
2401	+	number = {5},
2402	+	month = {Sep 8},
2403	+	abstract = {Backward error analysis has become an important tool for understanding
2404	+	the long time behavior of numerical integration methods. This is
2405	+	true in particular for the integration of Hamiltonian systems where
2406	+	backward error analysis can be used to show that a symplectic method
2407	+	will conserve energy over exponentially long periods of time. Such
2408	+	results are typically based on two aspects of backward error analysis:
2409	+	(i) It can be shown that the modified vector fields have some qualitative
2410	+	properties which they share with the given problem and (ii) an estimate
2411	+	is given for the difference between the best interpolating vector
2412	+	field and the numerical method. These aspects have been investigated
2413	+	recently, for example, by Benettin and Giorgilli in [J. Statist.
2414	+	Phys., 74 (1994), pp. 1117-1143], by Hairer in [Ann. Numer. Math.,
2415	+	1 (1994), pp. 107-132], and by Hairer and Lubich in [Numer. Math.,
2416	+	76 (1997), pp. 441-462]. In this paper we aim at providing a unifying
2417	+	framework and a simplification of the existing results and corresponding
2418	+	proofs. Our approach to backward error analysis is based on a simple
2419	+	recursive definition of the modified vector fields that does not
2420	+	require explicit Taylor series expansion of the numerical method
2421	+	and the corresponding flow maps as in the above-cited works. As
2422	+	an application we discuss the long time integration of chaotic Hamiltonian
2423	+	systems and the approximation of time averages along numerically
2424	+	computed trajectories.},
2425	+	annote = {237HV Times Cited:43 Cited References Count:41},
2426	+	issn = {0036-1429},
2427	+	uri = {<Go to ISI>://000082650600010},
2428	+	}
2429	+
2430		@ARTICLE{Ros2005,
2431		author = {M. B. Ros and J. L. Serrano and M. R. {de la Fuente} and C. L. Folcia},
2432		title = {Banana-shaped liquid crystals: a new field to explore},
#	Line 1939 | Line 2436 | Encoding: GBK
2436		pages = {5093-5098},
2437		number = {48},
2438		abstract = {The recent literature in the field of liquid crystals shows that banana-shaped
2439	<	mesogenic materials represent a bewitching and stimulating field
2440	<	of research that is interesting both academically and in terms of
2441	<	applications. Numerous topics are open to investigation in this
2442	<	area because of the rich phenomenology and new possibilities that
2443	<	these materials offer. The principal concepts in this area are reviewed
2444	<	along with recent results. In addition, new directions to stimulate
2445	<	further research activities are highlighted.},
2439	>	mesogenic materials represent a bewitching and stimulating field
2440	>	of research that is interesting both academically and in terms of
2441	>	applications. Numerous topics are open to investigation in this
2442	>	area because of the rich phenomenology and new possibilities that
2443	>	these materials offer. The principal concepts in this area are reviewed
2444	>	along with recent results. In addition, new directions to stimulate
2445	>	further research activities are highlighted.},
2446		annote = {990XA Times Cited:3 Cited References Count:72},
2447		issn = {0959-9428},
2448		uri = {<Go to ISI>://000233775500001},
#	Line 1954 | Line 2451 | Encoding: GBK
2451		@ARTICLE{Roy2005,
2452		author = {A. Roy and N. V. Madhusudana},
2453		title = {A frustrated packing model for the B-6-B-1-SmAP(A) sequence of phases
2454	<	in banana shaped molecules},
2454	>	in banana shaped molecules},
2455		journal = {European Physical Journal E},
2456		year = {2005},
2457		volume = {18},
#	Line 1962 | Line 2459 | Encoding: GBK
2459		number = {3},
2460		month = {Nov},
2461		abstract = {A vast majority of compounds with bent core or banana shaped molecules
2462	<	exhibit the phase sequence B-6-B-1-B-2 as the chain length is increased
2463	<	in a homologous series. The B-6 phase has an intercalated fluid
2464	<	lamellar structure with a layer spacing of half the molecular length.
2465	<	The B-1 phase has a two dimensionally periodic rectangular columnar
2466	<	structure. The B-2 phase has a monolayer fluid lamellar structure
2467	<	with molecules tilted with respect to the layer normal. Neglecting
2468	<	the tilt order of the molecules in the B-2 phase, we have developed
2469	<	a frustrated packing model to describe this phase sequence qualitatively.
2470	<	The model has some analogy with that of the frustrated smectics
2471	<	exhibited by highly polar rod like molecules.},
2462	>	exhibit the phase sequence B-6-B-1-B-2 as the chain length is increased
2463	>	in a homologous series. The B-6 phase has an intercalated fluid
2464	>	lamellar structure with a layer spacing of half the molecular length.
2465	>	The B-1 phase has a two dimensionally periodic rectangular columnar
2466	>	structure. The B-2 phase has a monolayer fluid lamellar structure
2467	>	with molecules tilted with respect to the layer normal. Neglecting
2468	>	the tilt order of the molecules in the B-2 phase, we have developed
2469	>	a frustrated packing model to describe this phase sequence qualitatively.
2470	>	The model has some analogy with that of the frustrated smectics
2471	>	exhibited by highly polar rod like molecules.},
2472		annote = {985FW Times Cited:0 Cited References Count:30},
2473		issn = {1292-8941},
2474		uri = {<Go to ISI>://000233363300002},
2475	+	}
2476	+
2477	+	@ARTICLE{Ryckaert1977,
2478	+	author = {J. P. Ryckaert and G. Ciccotti and H. J. C. Berendsen},
2479	+	title = {Numerical-Integration of Cartesian Equations of Motion of a System
2480	+	with Constraints - Molecular-Dynamics of N-Alkanes},
2481	+	journal = {Journal of Computational Physics},
2482	+	year = {1977},
2483	+	volume = {23},
2484	+	pages = {327-341},
2485	+	number = {3},
2486	+	annote = {Cz253 Times Cited:3680 Cited References Count:7},
2487	+	issn = {0021-9991},
2488	+	uri = {<Go to ISI>://A1977CZ25300007},
2489		}
2490
2491	+	@ARTICLE{Sagui1999,
2492	+	author = {C. Sagui and T. A. Darden},
2493	+	title = {Molecular dynamics simulations of biomolecules: Long-range electrostatic
2494	+	effects},
2495	+	journal = {Annual Review of Biophysics and Biomolecular Structure},
2496	+	year = {1999},
2497	+	volume = {28},
2498	+	pages = {155-179},
2499	+	abstract = {Current computer simulations of biomolecules typically make use of
2500	+	classical molecular dynamics methods, as a very large number (tens
2501	+	to hundreds of thousands) of atoms are involved over timescales
2502	+	of many nanoseconds. The methodology for treating short-range bonded
2503	+	and van der Waals interactions has matured. However, long-range
2504	+	electrostatic interactions still represent a bottleneck in simulations.
2505	+	In this article, we introduce the basic issues for an accurate representation
2506	+	of the relevant electrostatic interactions. In spite of the huge
2507	+	computational time demanded by most biomolecular systems, it is
2508	+	no longer necessary to resort to uncontrolled approximations such
2509	+	as the use of cutoffs. In particular, we discuss the Ewald summation
2510	+	methods, the fast particle mesh methods, and the fast multipole
2511	+	methods. We also review recent efforts to understand the role of
2512	+	boundary conditions in systems with long-range interactions, and
2513	+	conclude with a short perspective on future trends.},
2514	+	annote = {213KJ Times Cited:126 Cited References Count:73},
2515	+	issn = {1056-8700},
2516	+	uri = {<Go to ISI>://000081271400008},
2517	+	}
2518	+
2519		@ARTICLE{Sandu1999,
2520		author = {A. Sandu and T. Schlick},
2521		title = {Masking resonance artifacts in force-splitting methods for biomolecular
2522	<	simulations by extrapolative Langevin dynamics},
2522	>	simulations by extrapolative Langevin dynamics},
2523		journal = {Journal of Computational Physics},
2524		year = {1999},
2525		volume = {151},
#	Line 1988 | Line 2527 | Encoding: GBK
2527		number = {1},
2528		month = {May 1},
2529		abstract = {Numerical resonance artifacts have become recognized recently as a
2530	<	limiting factor to increasing the timestep in multiple-timestep
2531	<	(MTS) biomolecular dynamics simulations. At certain timesteps correlated
2532	<	to internal motions (e.g., 5 fs, around half the period of the fastest
2533	<	bond stretch, T-min), visible inaccuracies or instabilities can
2534	<	occur. Impulse-MTS schemes are vulnerable to these resonance errors
2535	<	since large energy pulses are introduced to the governing dynamics
2536	<	equations when the slow forces are evaluated. We recently showed
2537	<	that such resonance artifacts can be masked significantly by applying
2538	<	extrapolative splitting to stochastic dynamics. Theoretical and
2539	<	numerical analyses of force-splitting integrators based on the Verlet
2540	<	discretization are reported here for linear models to explain these
2541	<	observations and to suggest how to construct effective integrators
2542	<	for biomolecular dynamics that balance stability with accuracy.
2543	<	Analyses for Newtonian dynamics demonstrate the severe resonance
2544	<	patterns of the Impulse splitting, with this severity worsening
2545	<	with the outer timestep. Delta t: Constant Extrapolation is generally
2546	<	unstable, but the disturbances do not grow with Delta t. Thus. the
2547	<	stochastic extrapolative combination can counteract generic instabilities
2548	<	and largely alleviate resonances with a sufficiently strong Langevin
2549	<	heat-bath coupling (gamma), estimates for which are derived here
2550	<	based on the fastest and slowest motion periods. These resonance
2551	<	results generally hold for nonlinear test systems: a water tetramer
2552	<	and solvated protein. Proposed related approaches such as Extrapolation/Correction
2553	<	and Midpoint Extrapolation work better than Constant Extrapolation
2554	<	only for timesteps less than T-min/2. An effective extrapolative
2555	<	stochastic approach for biomolecules that balances long-timestep
2556	<	stability with good accuracy for the fast subsystem is then applied
2557	<	to a biomolecule using a three-class partitioning: the medium forces
2558	<	are treated by Midpoint Extrapolation via position Verlet, and the
2559	<	slow forces are incorporated by Constant Extrapolation. The resulting
2560	<	algorithm (LN) performs well on a solvated protein system in terms
2561	<	of thermodynamic properties and yields an order of magnitude speedup
2562	<	with respect to single-timestep Langevin trajectories. Computed
2563	<	spectral density functions also show how the Newtonian modes can
2564	<	be approximated by using a small gamma in the range Of 5-20 ps(-1).
2565	<	(C) 1999 Academic Press.},
2530	>	limiting factor to increasing the timestep in multiple-timestep
2531	>	(MTS) biomolecular dynamics simulations. At certain timesteps correlated
2532	>	to internal motions (e.g., 5 fs, around half the period of the fastest
2533	>	bond stretch, T-min), visible inaccuracies or instabilities can
2534	>	occur. Impulse-MTS schemes are vulnerable to these resonance errors
2535	>	since large energy pulses are introduced to the governing dynamics
2536	>	equations when the slow forces are evaluated. We recently showed
2537	>	that such resonance artifacts can be masked significantly by applying
2538	>	extrapolative splitting to stochastic dynamics. Theoretical and
2539	>	numerical analyses of force-splitting integrators based on the Verlet
2540	>	discretization are reported here for linear models to explain these
2541	>	observations and to suggest how to construct effective integrators
2542	>	for biomolecular dynamics that balance stability with accuracy.
2543	>	Analyses for Newtonian dynamics demonstrate the severe resonance
2544	>	patterns of the Impulse splitting, with this severity worsening
2545	>	with the outer timestep. Delta t: Constant Extrapolation is generally
2546	>	unstable, but the disturbances do not grow with Delta t. Thus. the
2547	>	stochastic extrapolative combination can counteract generic instabilities
2548	>	and largely alleviate resonances with a sufficiently strong Langevin
2549	>	heat-bath coupling (gamma), estimates for which are derived here
2550	>	based on the fastest and slowest motion periods. These resonance
2551	>	results generally hold for nonlinear test systems: a water tetramer
2552	>	and solvated protein. Proposed related approaches such as Extrapolation/Correction
2553	>	and Midpoint Extrapolation work better than Constant Extrapolation
2554	>	only for timesteps less than T-min/2. An effective extrapolative
2555	>	stochastic approach for biomolecules that balances long-timestep
2556	>	stability with good accuracy for the fast subsystem is then applied
2557	>	to a biomolecule using a three-class partitioning: the medium forces
2558	>	are treated by Midpoint Extrapolation via position Verlet, and the
2559	>	slow forces are incorporated by Constant Extrapolation. The resulting
2560	>	algorithm (LN) performs well on a solvated protein system in terms
2561	>	of thermodynamic properties and yields an order of magnitude speedup
2562	>	with respect to single-timestep Langevin trajectories. Computed
2563	>	spectral density functions also show how the Newtonian modes can
2564	>	be approximated by using a small gamma in the range Of 5-20 ps(-1).
2565	>	(C) 1999 Academic Press.},
2566		annote = {194FM Times Cited:14 Cited References Count:32},
2567		issn = {0021-9991},
2568		uri = {<Go to ISI>://000080181500004},
#	Line 2032 | Line 2571 | Encoding: GBK
2571		@ARTICLE{Satoh1996,
2572		author = {K. Satoh and S. Mita and S. Kondo},
2573		title = {Monte Carlo simulations using the dipolar Gay-Berne model: Effect
2574	<	of terminal dipole moment on mesophase formation},
2574	>	of terminal dipole moment on mesophase formation},
2575		journal = {Chemical Physics Letters},
2576		year = {1996},
2577		volume = {255},
#	Line 2040 | Line 2579 | Encoding: GBK
2579		number = {1-3},
2580		month = {Jun 7},
2581		abstract = {The effects of dipole-dipole interaction on mesophase formation are
2582	<	investigated with a Monte Carlo simulation using the dipolar Gay-Berne
2583	<	potential. It is shown that the dipole moment at the end of a molecule
2584	<	causes a shift in the nematic-isotropic transition toward higher
2585	<	temperature and a spread of the temperature range of the nematic
2586	<	phase and that layer structures with various interdigitations are
2587	<	formed in the smectic phase.},
2582	>	investigated with a Monte Carlo simulation using the dipolar Gay-Berne
2583	>	potential. It is shown that the dipole moment at the end of a molecule
2584	>	causes a shift in the nematic-isotropic transition toward higher
2585	>	temperature and a spread of the temperature range of the nematic
2586	>	phase and that layer structures with various interdigitations are
2587	>	formed in the smectic phase.},
2588		annote = {Uq975 Times Cited:32 Cited References Count:33},
2589		issn = {0009-2614},
2590		uri = {<Go to ISI>://A1996UQ97500017},
#	Line 2054 | Line 2593 | Encoding: GBK
2593		@ARTICLE{Shen2002,
2594		author = {M. Y. Shen and K. F. Freed},
2595		title = {Long time dynamics of met-enkephalin: Comparison of explicit and
2596	<	implicit solvent models},
2596	>	implicit solvent models},
2597		journal = {Biophysical Journal},
2598		year = {2002},
2599		volume = {82},
#	Line 2062 | Line 2601 | Encoding: GBK
2601		number = {4},
2602		month = {Apr},
2603		abstract = {Met-enkephalin is one of the smallest opiate peptides. Yet, its dynamical
2604	<	structure and receptor docking mechanism are still not well understood.
2605	<	The conformational dynamics of this neuron peptide in liquid water
2606	<	are studied here by using all-atom molecular dynamics (MID) and
2607	<	implicit water Langevin dynamics (LD) simulations with AMBER potential
2608	<	functions and the three-site transferable intermolecular potential
2609	<	(TIP3P) model for water. To achieve the same simulation length in
2610	<	physical time, the full MID simulations require 200 times as much
2611	<	CPU time as the implicit water LID simulations. The solvent hydrophobicity
2612	<	and dielectric behavior are treated in the implicit solvent LD simulations
2613	<	by using a macroscopic solvation potential, a single dielectric
2614	<	constant, and atomic friction coefficients computed using the accessible
2615	<	surface area method with the TIP3P model water viscosity as determined
2616	<	here from MID simulations for pure TIP3P water. Both the local and
2617	<	the global dynamics obtained from the implicit solvent LD simulations
2618	<	agree very well with those from the explicit solvent MD simulations.
2619	<	The simulations provide insights into the conformational restrictions
2620	<	that are associated with the bioactivity of the opiate peptide dermorphin
2621	<	for the delta-receptor.},
2604	>	structure and receptor docking mechanism are still not well understood.
2605	>	The conformational dynamics of this neuron peptide in liquid water
2606	>	are studied here by using all-atom molecular dynamics (MID) and
2607	>	implicit water Langevin dynamics (LD) simulations with AMBER potential
2608	>	functions and the three-site transferable intermolecular potential
2609	>	(TIP3P) model for water. To achieve the same simulation length in
2610	>	physical time, the full MID simulations require 200 times as much
2611	>	CPU time as the implicit water LID simulations. The solvent hydrophobicity
2612	>	and dielectric behavior are treated in the implicit solvent LD simulations
2613	>	by using a macroscopic solvation potential, a single dielectric
2614	>	constant, and atomic friction coefficients computed using the accessible
2615	>	surface area method with the TIP3P model water viscosity as determined
2616	>	here from MID simulations for pure TIP3P water. Both the local and
2617	>	the global dynamics obtained from the implicit solvent LD simulations
2618	>	agree very well with those from the explicit solvent MD simulations.
2619	>	The simulations provide insights into the conformational restrictions
2620	>	that are associated with the bioactivity of the opiate peptide dermorphin
2621	>	for the delta-receptor.},
2622		annote = {540MH Times Cited:36 Cited References Count:45},
2623		issn = {0006-3495},
2624		uri = {<Go to ISI>://000174932400010},
#	Line 2099 | Line 2638 | Encoding: GBK
2638		uri = {<Go to ISI>://000227296700019},
2639		}
2640
2641	+	@ARTICLE{Shimada1993,
2642	+	author = {J. Shimada and H. Kaneko and T. Takada},
2643	+	title = {Efficient Calculations of Coulombic Interactions in Biomolecular
2644	+	Simulations with Periodic Boundary-Conditions},
2645	+	journal = {Journal of Computational Chemistry},
2646	+	year = {1993},
2647	+	volume = {14},
2648	+	pages = {867-878},
2649	+	number = {7},
2650	+	month = {Jul},
2651	+	abstract = {To make improved treatments of electrostatic interactions in biomacromolecular
2652	+	simulations, two possibilities are considered. The first is the
2653	+	famous particle-particle and particle-mesh (PPPM) method developed
2654	+	by Hockney and Eastwood, and the second is a new one developed here
2655	+	in their spirit but by the use of the multipole expansion technique
2656	+	suggested by Ladd. It is then numerically found that the new PPPM
2657	+	method gives more accurate results for a two-particle system at
2658	+	small separation of particles. Preliminary numerical examination
2659	+	of the various computational methods for a single configuration
2660	+	of a model BPTI-water system containing about 24,000 particles indicates
2661	+	that both of the PPPM methods give far more accurate values with
2662	+	reasonable computational cost than do the conventional truncation
2663	+	methods. It is concluded the two PPPM methods are nearly comparable
2664	+	in overall performance for the many-particle systems, although the
2665	+	first method has the drawback that the accuracy in the total electrostatic
2666	+	energy is not high for configurations of charged particles randomly
2667	+	generated.},
2668	+	annote = {Lh164 Times Cited:27 Cited References Count:47},
2669	+	issn = {0192-8651},
2670	+	uri = {<Go to ISI>://A1993LH16400011},
2671	+	}
2672	+
2673		@ARTICLE{Skeel2002,
2674		author = {R. D. Skeel and J. A. Izaguirre},
2675		title = {An impulse integrator for Langevin dynamics},
#	Line 2109 | Line 2680 | Encoding: GBK
2680		number = {24},
2681		month = {Dec 20},
2682		abstract = {The best simple method for Newtonian molecular dynamics is indisputably
2683	<	the leapfrog Stormer-Verlet method. The appropriate generalization
2684	<	to simple Langevin dynamics is unclear. An analysis is presented
2685	<	comparing an 'impulse method' (kick; fluctuate; kick), the 1982
2686	<	method of van Gunsteren and Berendsen, and the Brunger-Brooks-Karplus
2687	<	(BBK) method. It is shown how the impulse method and the van Gunsteren-Berendsen
2688	<	methods can be implemented as efficiently as the BBK method. Other
2689	<	considerations suggest that the impulse method is the best basic
2690	<	method for simple Langevin dynamics, with the van Gunsteren-Berendsen
2691	<	method a close contender.},
2683	>	the leapfrog Stormer-Verlet method. The appropriate generalization
2684	>	to simple Langevin dynamics is unclear. An analysis is presented
2685	>	comparing an 'impulse method' (kick; fluctuate; kick), the 1982
2686	>	method of van Gunsteren and Berendsen, and the Brunger-Brooks-Karplus
2687	>	(BBK) method. It is shown how the impulse method and the van Gunsteren-Berendsen
2688	>	methods can be implemented as efficiently as the BBK method. Other
2689	>	considerations suggest that the impulse method is the best basic
2690	>	method for simple Langevin dynamics, with the van Gunsteren-Berendsen
2691	>	method a close contender.},
2692		annote = {633RX Times Cited:8 Cited References Count:22},
2693		issn = {0026-8976},
2694		uri = {<Go to ISI>://000180297200014},
#	Line 2126 | Line 2697 | Encoding: GBK
2697		@ARTICLE{Skeel1997,
2698		author = {R. D. Skeel and G. H. Zhang and T. Schlick},
2699		title = {A family of symplectic integrators: Stability, accuracy, and molecular
2700	<	dynamics applications},
2700	>	dynamics applications},
2701		journal = {Siam Journal on Scientific Computing},
2702		year = {1997},
2703		volume = {18},
#	Line 2134 | Line 2705 | Encoding: GBK
2705		number = {1},
2706		month = {Jan},
2707		abstract = {The following integration methods for special second-order ordinary
2708	<	differential equations are studied: leapfrog, implicit midpoint,
2709	<	trapezoid, Stormer-Verlet, and Cowell-Numerov. We show that all
2710	<	are members, or equivalent to members, of a one-parameter family
2711	<	of schemes. Some methods have more than one common form, and we
2712	<	discuss a systematic enumeration of these forms. We also present
2713	<	a stability and accuracy analysis based on the idea of ''modified
2714	<	equations'' and a proof of symplecticness. It follows that Cowell-Numerov
2715	<	and ''LIM2'' (a method proposed by Zhang and Schlick) are symplectic.
2716	<	A different interpretation of the values used by these integrators
2717	<	leads to higher accuracy and better energy conservation. Hence,
2718	<	we suggest that the straightforward analysis of energy conservation
2719	<	is misleading.},
2708	>	differential equations are studied: leapfrog, implicit midpoint,
2709	>	trapezoid, Stormer-Verlet, and Cowell-Numerov. We show that all
2710	>	are members, or equivalent to members, of a one-parameter family
2711	>	of schemes. Some methods have more than one common form, and we
2712	>	discuss a systematic enumeration of these forms. We also present
2713	>	a stability and accuracy analysis based on the idea of ''modified
2714	>	equations'' and a proof of symplecticness. It follows that Cowell-Numerov
2715	>	and ''LIM2'' (a method proposed by Zhang and Schlick) are symplectic.
2716	>	A different interpretation of the values used by these integrators
2717	>	leads to higher accuracy and better energy conservation. Hence,
2718	>	we suggest that the straightforward analysis of energy conservation
2719	>	is misleading.},
2720		annote = {We981 Times Cited:30 Cited References Count:35},
2721		issn = {1064-8275},
2722		uri = {<Go to ISI>://A1997WE98100012},
#	Line 2153 | Line 2724 | Encoding: GBK
2724
2725		@ARTICLE{Tao2005,
2726		author = {Y. G. Tao and W. K. {den Otter} and J. T. Padding and J. K. G. Dhont
2727	<	and W. J. Briels},
2727	>	and W. J. Briels},
2728		title = {Brownian dynamics simulations of the self- and collective rotational
2729	<	diffusion coefficients of rigid long thin rods},
2729	>	diffusion coefficients of rigid long thin rods},
2730		journal = {Journal of Chemical Physics},
2731		year = {2005},
2732		volume = {122},
#	Line 2163 | Line 2734 | Encoding: GBK
2734		number = {24},
2735		month = {Jun 22},
2736		abstract = {Recently a microscopic theory for the dynamics of suspensions of long
2737	<	thin rigid rods was presented, confirming and expanding the well-known
2738	<	theory by Doi and Edwards [The Theory of Polymer Dynamics (Clarendon,
2739	<	Oxford, 1986)] and Kuzuu [J. Phys. Soc. Jpn. 52, 3486 (1983)]. Here
2740	<	this theory is put to the test by comparing it against computer
2741	<	simulations. A Brownian dynamics simulation program was developed
2742	<	to follow the dynamics of the rods, with a length over a diameter
2743	<	ratio of 60, on the Smoluchowski time scale. The model accounts
2744	<	for excluded volume interactions between rods, but neglects hydrodynamic
2745	<	interactions. The self-rotational diffusion coefficients D-r(phi)
2746	<	of the rods were calculated by standard methods and by a new, more
2747	<	efficient method based on calculating average restoring torques.
2748	<	Collective decay of orientational order was calculated by means
2749	<	of equilibrium and nonequilibrium simulations. Our results show
2750	<	that, for the currently accessible volume fractions, the decay times
2751	<	in both cases are virtually identical. Moreover, the observed decay
2752	<	of diffusion coefficients with volume fraction is much quicker than
2753	<	predicted by the theory, which is attributed to an oversimplification
2754	<	of dynamic correlations in the theory. (c) 2005 American Institute
2755	<	of Physics.},
2737	>	thin rigid rods was presented, confirming and expanding the well-known
2738	>	theory by Doi and Edwards [The Theory of Polymer Dynamics (Clarendon,
2739	>	Oxford, 1986)] and Kuzuu [J. Phys. Soc. Jpn. 52, 3486 (1983)]. Here
2740	>	this theory is put to the test by comparing it against computer
2741	>	simulations. A Brownian dynamics simulation program was developed
2742	>	to follow the dynamics of the rods, with a length over a diameter
2743	>	ratio of 60, on the Smoluchowski time scale. The model accounts
2744	>	for excluded volume interactions between rods, but neglects hydrodynamic
2745	>	interactions. The self-rotational diffusion coefficients D-r(phi)
2746	>	of the rods were calculated by standard methods and by a new, more
2747	>	efficient method based on calculating average restoring torques.
2748	>	Collective decay of orientational order was calculated by means
2749	>	of equilibrium and nonequilibrium simulations. Our results show
2750	>	that, for the currently accessible volume fractions, the decay times
2751	>	in both cases are virtually identical. Moreover, the observed decay
2752	>	of diffusion coefficients with volume fraction is much quicker than
2753	>	predicted by the theory, which is attributed to an oversimplification
2754	>	of dynamic correlations in the theory. (c) 2005 American Institute
2755	>	of Physics.},
2756		annote = {943DN Times Cited:3 Cited References Count:26},
2757		issn = {0021-9606},
2758		uri = {<Go to ISI>://000230332400077},
#	Line 2200 | Line 2771 | Encoding: GBK
2771		@ARTICLE{Tu1995,
2772		author = {K. Tu and D. J. Tobias and M. L. Klein},
2773		title = {Constant pressure and temperature molecular dynamics simulation of
2774	<	a fully hydrated liquid crystal phase dipalmitoylphosphatidylcholine
2775	<	bilayer},
2774	>	a fully hydrated liquid crystal phase dipalmitoylphosphatidylcholine
2775	>	bilayer},
2776		journal = {Biophysical Journal},
2777		year = {1995},
2778		volume = {69},
#	Line 2209 | Line 2780 | Encoding: GBK
2780		number = {6},
2781		month = {Dec},
2782		abstract = {We report a constant pressure and temperature molecular dynamics simulation
2783	<	of a fully hydrated liquid crystal (L(alpha) phase bilayer of dipalmitoylphosphatidylcholine
2784	<	at 50 degrees C and 28 water molecules/lipid. We have shown that
2785	<	the bilayer is stable throughout the 1550-ps simulation and have
2786	<	demonstrated convergence of the system dimensions. Several important
2787	<	aspects of the bilayer structure have been investigated and compared
2788	<	favorably with experimental results. For example, the average positions
2789	<	of specific carbon atoms along the bilayer normal agree well with
2790	<	neutron diffraction data, and the electron density profile is in
2791	<	accord with x-ray diffraction results. The hydrocarbon chain deuterium
2792	<	order parameters agree reasonably well with NMR results for the
2793	<	middles of the chains, but the simulation predicts too much order
2794	<	at the chain ends. In spite of the deviations in the order parameters,
2795	<	the hydrocarbon chain packing density appears to be essentially
2796	<	correct, inasmuch as the area/lipid and bilayer thickness are in
2797	<	agreement with the most refined experimental estimates. The deuterium
2798	<	order parameters for the glycerol and choline groups, as well as
2799	<	the phosphorus chemical shift anisotropy, are in qualitative agreement
2800	<	with those extracted from NMR measurements.},
2783	>	of a fully hydrated liquid crystal (L(alpha) phase bilayer of dipalmitoylphosphatidylcholine
2784	>	at 50 degrees C and 28 water molecules/lipid. We have shown that
2785	>	the bilayer is stable throughout the 1550-ps simulation and have
2786	>	demonstrated convergence of the system dimensions. Several important
2787	>	aspects of the bilayer structure have been investigated and compared
2788	>	favorably with experimental results. For example, the average positions
2789	>	of specific carbon atoms along the bilayer normal agree well with
2790	>	neutron diffraction data, and the electron density profile is in
2791	>	accord with x-ray diffraction results. The hydrocarbon chain deuterium
2792	>	order parameters agree reasonably well with NMR results for the
2793	>	middles of the chains, but the simulation predicts too much order
2794	>	at the chain ends. In spite of the deviations in the order parameters,
2795	>	the hydrocarbon chain packing density appears to be essentially
2796	>	correct, inasmuch as the area/lipid and bilayer thickness are in
2797	>	agreement with the most refined experimental estimates. The deuterium
2798	>	order parameters for the glycerol and choline groups, as well as
2799	>	the phosphorus chemical shift anisotropy, are in qualitative agreement
2800	>	with those extracted from NMR measurements.},
2801		annote = {Tv018 Times Cited:108 Cited References Count:34},
2802		issn = {0006-3495},
2803		uri = {<Go to ISI>://A1995TV01800037},
#	Line 2242 | Line 2813 | Encoding: GBK
2813		number = {3},
2814		month = {Aug 1},
2815		abstract = {The Trotter factorization of the Liouville propagator is used to generate
2816	<	new reversible molecular dynamics integrators. This strategy is
2817	<	applied to derive reversible reference system propagator algorithms
2818	<	(RESPA) that greatly accelerate simulations of systems with a separation
2819	<	of time scales or with long range forces. The new algorithms have
2820	<	all of the advantages of previous RESPA integrators but are reversible,
2821	<	and more stable than those methods. These methods are applied to
2822	<	a set of paradigmatic systems and are shown to be superior to earlier
2823	<	methods. It is shown how the new RESPA methods are related to predictor-corrector
2824	<	integrators. Finally, we show how these methods can be used to accelerate
2825	<	the integration of the equations of motion of systems with Nose
2826	<	thermostats.},
2816	>	new reversible molecular dynamics integrators. This strategy is
2817	>	applied to derive reversible reference system propagator algorithms
2818	>	(RESPA) that greatly accelerate simulations of systems with a separation
2819	>	of time scales or with long range forces. The new algorithms have
2820	>	all of the advantages of previous RESPA integrators but are reversible,
2821	>	and more stable than those methods. These methods are applied to
2822	>	a set of paradigmatic systems and are shown to be superior to earlier
2823	>	methods. It is shown how the new RESPA methods are related to predictor-corrector
2824	>	integrators. Finally, we show how these methods can be used to accelerate
2825	>	the integration of the equations of motion of systems with Nose
2826	>	thermostats.},
2827		annote = {Je891 Times Cited:680 Cited References Count:19},
2828		issn = {0021-9606},
2829		uri = {<Go to ISI>://A1992JE89100044},
2830		}
2831
2832	+	@BOOK{Varadarajan1974,
2833	+	title = {Lie groups, Lie algebras, and their representations},
2834	+	publisher = {Prentice-Hall},
2835	+	year = {1974},
2836	+	author = {V.S. Varadarajan},
2837	+	address = {New York},
2838	+	}
2839	+
2840		@ARTICLE{Wegener1979,
2841		author = {W.~A. Wegener, V.~J. Koester and R.~M. Dowben},
2842		title = {A general ellipsoid can not always serve as a modle for the rotational
2843	<	diffusion properties of arbitrary shaped rigid molecules},
2843	>	diffusion properties of arbitrary shaped rigid molecules},
2844		journal = {Proc. Natl. Acad. Sci.},
2845		year = {1979},
2846		volume = {76},
#	Line 2272 | Line 2851 | Encoding: GBK
2851		@ARTICLE{Withers2003,
2852		author = {I. M. Withers},
2853		title = {Effects of longitudinal quadrupoles on the phase behavior of a Gay-Berne
2854	<	fluid},
2854	>	fluid},
2855		journal = {Journal of Chemical Physics},
2856		year = {2003},
2857		volume = {119},
#	Line 2280 | Line 2859 | Encoding: GBK
2859		number = {19},
2860		month = {Nov 15},
2861		abstract = {The effects of longitudinal quadrupole moments on the formation of
2862	<	liquid crystalline phases are studied by means of constant NPT Monte
2863	<	Carlo simulation methods. The popular Gay-Berne model mesogen is
2864	<	used as the reference fluid, which displays the phase sequences
2865	<	isotropic-smectic A-smectic B and isotropic-smectic B at high (T*=2.0)
2866	<	and low (T*=1.5) temperatures, respectively. With increasing quadrupole
2867	<	magnitude the smectic phases are observed to be stabilized with
2868	<	respect to the isotropic liquid, while the smectic B is destabilized
2869	<	with respect to the smectic A. At the lower temperature, a sufficiently
2870	<	large quadrupole magnitude results in the injection of the smectic
2871	<	A phase into the phase sequence and the replacement of the smectic
2872	<	B phase by the tilted smectic J phase. The nematic phase is also
2873	<	injected into the phase sequence at both temperatures considered,
2874	<	and ultimately for sufficiently large quadrupole magnitudes no coherent
2875	<	layered structures were observed. The stabilization of the smectic
2876	<	A phase supports the commonly held belief that, while the inclusion
2877	<	of polar groups is not a prerequisite for the formation of the smectic
2878	<	A phase, quadrupolar interactions help to increase the temperature
2879	<	and pressure range for which the smectic A phase is observed. The
2880	<	quality of the layered structure is worsened with increasing quadrupole
2881	<	magnitude. This behavior, along with the injection of the nematic
2882	<	phase into the phase sequence, indicate that the general tendency
2883	<	of the quadrupolar interactions is to destabilize the layered structure.
2884	<	A pressure dependence upon the smectic layer spacing is observed.
2885	<	This behavior is in much closer agreement with experimental findings
2886	<	than has been observed previously for nonpolar Gay-Berne and hard
2887	<	spherocylinder models. (C) 2003 American Institute of Physics.},
2862	>	liquid crystalline phases are studied by means of constant NPT Monte
2863	>	Carlo simulation methods. The popular Gay-Berne model mesogen is
2864	>	used as the reference fluid, which displays the phase sequences
2865	>	isotropic-smectic A-smectic B and isotropic-smectic B at high (T*=2.0)
2866	>	and low (T*=1.5) temperatures, respectively. With increasing quadrupole
2867	>	magnitude the smectic phases are observed to be stabilized with
2868	>	respect to the isotropic liquid, while the smectic B is destabilized
2869	>	with respect to the smectic A. At the lower temperature, a sufficiently
2870	>	large quadrupole magnitude results in the injection of the smectic
2871	>	A phase into the phase sequence and the replacement of the smectic
2872	>	B phase by the tilted smectic J phase. The nematic phase is also
2873	>	injected into the phase sequence at both temperatures considered,
2874	>	and ultimately for sufficiently large quadrupole magnitudes no coherent
2875	>	layered structures were observed. The stabilization of the smectic
2876	>	A phase supports the commonly held belief that, while the inclusion
2877	>	of polar groups is not a prerequisite for the formation of the smectic
2878	>	A phase, quadrupolar interactions help to increase the temperature
2879	>	and pressure range for which the smectic A phase is observed. The
2880	>	quality of the layered structure is worsened with increasing quadrupole
2881	>	magnitude. This behavior, along with the injection of the nematic
2882	>	phase into the phase sequence, indicate that the general tendency
2883	>	of the quadrupolar interactions is to destabilize the layered structure.
2884	>	A pressure dependence upon the smectic layer spacing is observed.
2885	>	This behavior is in much closer agreement with experimental findings
2886	>	than has been observed previously for nonpolar Gay-Berne and hard
2887	>	spherocylinder models. (C) 2003 American Institute of Physics.},
2888		annote = {738EF Times Cited:3 Cited References Count:43},
2889		issn = {0021-9606},
2890		uri = {<Go to ISI>://000186273200027},
2891		}
2892
2893	+	@ARTICLE{Wolf1999,
2894	+	author = {D. Wolf and P. Keblinski and S. R. Phillpot and J. Eggebrecht},
2895	+	title = {Exact method for the simulation of Coulombic systems by spherically
2896	+	truncated, pairwise r(-1) summation},
2897	+	journal = {Journal of Chemical Physics},
2898	+	year = {1999},
2899	+	volume = {110},
2900	+	pages = {8254-8282},
2901	+	number = {17},
2902	+	month = {May 1},
2903	+	abstract = {Based on a recent result showing that the net Coulomb potential in
2904	+	condensed ionic systems is rather short ranged, an exact and physically
2905	+	transparent method permitting the evaluation of the Coulomb potential
2906	+	by direct summation over the r(-1) Coulomb pair potential is presented.
2907	+	The key observation is that the problems encountered in determining
2908	+	the Coulomb energy by pairwise, spherically truncated r(-1) summation
2909	+	are a direct consequence of the fact that the system summed over
2910	+	is practically never neutral. A simple method is developed that
2911	+	achieves charge neutralization wherever the r(-1) pair potential
2912	+	is truncated. This enables the extraction of the Coulomb energy,
2913	+	forces, and stresses from a spherically truncated, usually charged
2914	+	environment in a manner that is independent of the grouping of the
2915	+	pair terms. The close connection of our approach with the Ewald
2916	+	method is demonstrated and exploited, providing an efficient method
2917	+	for the simulation of even highly disordered ionic systems by direct,
2918	+	pairwise r(-1) summation with spherical truncation at rather short
2919	+	range, i.e., a method which fully exploits the short-ranged nature
2920	+	of the interactions in ionic systems. The method is validated by
2921	+	simulations of crystals, liquids, and interfacial systems, such
2922	+	as free surfaces and grain boundaries. (C) 1999 American Institute
2923	+	of Physics. [S0021-9606(99)51517-1].},
2924	+	annote = {189PD Times Cited:70 Cited References Count:34},
2925	+	issn = {0021-9606},
2926	+	uri = {<Go to ISI>://000079913000008},
2927	+	}
2928	+
2929	+	@ARTICLE{Yoshida1990,
2930	+	author = {H. Yoshida},
2931	+	title = {Construction of Higher-Order Symplectic Integrators},
2932	+	journal = {Physics Letters A},
2933	+	year = {1990},
2934	+	volume = {150},
2935	+	pages = {262-268},
2936	+	number = {5-7},
2937	+	month = {Nov 12},
2938	+	annote = {Ej798 Times Cited:492 Cited References Count:9},
2939	+	issn = {0375-9601},
2940	+	uri = {<Go to ISI>://A1990EJ79800009},
2941	+	}
2942	+
2943	+	@Book{Frenkel1996,
2944	+	author =   {D. Frenkel and B. Smit},
2945	+	title =    {Understanding Molecular Simulation : From Algorithms
2946	+	to Applications},
2947	+	publisher =    {Academic Press},
2948	+	year =     1996,
2949	+	address =  {New York}
2950	+	}

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