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1 %% This BibTeX bibliography file was created using BibDesk.
2 %% http://bibdesk.sourceforge.net/
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5 %% Created for Shenyu Kuang at 2010-07-22 13:37:27 -0400
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8 %% Saved with string encoding Western (ASCII)
9
10
11
12 @inbook{Hoffman:2001sf,
13 Address = {New York},
14 Annote = {LDR 01107cam 2200253 a 4500
15 001 12358442
16 005 20070910074423.0
17 008 010326s2001 nyua b 001 0 eng
18 906 $a7$bcbc$corignew$d1$eocip$f20$gy-gencatlg
19 925 0 $aacquire$b2 shelf copies$xpolicy default
20 955 $ato ASCD pc23 03-26-01; jp20 03-27-01 to subj; jp99 to SL 03-27-01; jp85 to Dewey 03-27-01; aa01 03-28-01$aps02 2001-10-04 bk rec'd, to CIP ver.;$fpv04 2001-10-31 CIP ver to BCCD$ajp01 2001-12-06 c. 2 to BCCD
21 010 $a 2001028633
22 020 $a0824704436 (acid-free paper)
23 040 $aDLC$cDLC$dDLC
24 050 00 $aQA297$b.H588 2001
25 082 00 $a519.4$221
26 100 1 $aHoffman, Joe D.,$d1934-
27 245 10 $aNumerical methods for engineers and scientists /$cJoe D. Hoffman.
28 250 $a2nd ed., rev. and expanded.
29 260 $aNew York :$bMarcel Dekker,$cc2001.
30 300 $axi, 823 p. :$bill. ;$c26 cm.
31 504 $aIncludes bibliographical references (p. 775-777) and index.
32 650 0 $aNumerical analysis.
33 856 42 $3Publisher description$uhttp://www.loc.gov/catdir/enhancements/fy0743/2001028633-d.html
34 },
35 Author = {Hoffman, Joe D.},
36 Call-Number = {QA297},
37 Date-Added = {2010-07-15 16:32:02 -0400},
38 Date-Modified = {2010-07-19 16:49:37 -0400},
39 Dewey-Call-Number = {519.4},
40 Edition = {2nd ed., rev. and expanded},
41 Genre = {Numerical analysis},
42 Isbn = {0824704436 (acid-free paper)},
43 Library-Id = {2001028633},
44 Pages = {157},
45 Publisher = {Marcel Dekker},
46 Title = {Numerical methods for engineers and scientists},
47 Url = {http://www.loc.gov/catdir/enhancements/fy0743/2001028633-d.html},
48 Year = {2001},
49 Bdsk-Url-1 = {http://www.loc.gov/catdir/enhancements/fy0743/2001028633-d.html}}
50
51 @article{Vardeman:2008fk,
52 Abstract = {Using molecular dynamics simulations, we have simulated the rapid cooling experienced by bimetallic nanoparticles following laser excitation at the plasmon resonance and find evidence that glassy beads, specifically Ag-Cu bimetallic particles at the eutectic composition (60\% Ag, 40\% Cu), can be formed during these experiments. The bimetallic nanoparticles are embedded in an implicit solvent with a viscosity tuned to yield cooling curves that match the experimental cooling behavior as closely as possible. Because the nanoparticles have a large surface-to-volume ratio, experimentally realistic cooling rates are accessible via relatively short simulations. The presence of glassy structural features was verified using bond orientational order parameters that are sensitive to the formation of local icosahedral ordering in condensed phases. As the particles cool from the liquid droplet state into glassy beads, a silver-rich monolayer develops on the outer surface and local icosahedra can develop around the silver atoms in this monolayer. However, we observe a strong preference for the local icosahedral ordering around the copper atoms in the particles. As the particles cool, these local icosahedral structures grow to include a larger fraction of the atoms in the nanoparticle, eventually leading to a glassy nanosphere.},
53 Address = {1155 16TH ST, NW, WASHINGTON, DC 20036 USA},
54 Author = {{Vardeman II}, Charles F. and Gezelter, J. Daniel},
55 Date-Added = {2010-07-13 11:48:22 -0400},
56 Date-Modified = {2010-07-19 16:20:01 -0400},
57 Doi = {DOI 10.1021/jp710063g},
58 Isi = {000253512400021},
59 Isi-Recid = {160903603},
60 Isi-Ref-Recids = {144152922 81445483 98913099 146167982 55512304 50985260 52031423 29272311 151055545 134895634 130292830 101988637 100757730 98524559 123952006 6025131 59492217 2078548 135495737 136941603 90709964 160903604 130558416 113800688 30137926 117888234 63632785 38926953 158293976 135246439 125693419 125789026 155583142 156430464 65888620 130160487 97576420 109490154 150229560 116057234 134425927 142869781 121706070 89390336 119150946 143383743 64066027 171282998 142688207 51429664 84591083 127696312 58160909 155366996 155654757 137551818 128633299 109033408 120457571 171282999 124947095 126857514 49630702 64115284 84689627 71842426 96309965 79034659 92658330 146168029 119238036 144824430 132319357 160903607 171283000 100274448},
61 Journal = {Journal of Physical Chemistry C},
62 Month = mar,
63 Number = {9},
64 Pages = {3283-3293},
65 Publisher = {AMER CHEMICAL SOC},
66 Times-Cited = {0},
67 Title = {Simulations of laser-induced glass formation in Ag-Cu nanoparticles},
68 Volume = {112},
69 Year = {2008},
70 Bdsk-Url-1 = {http://gateway.isiknowledge.com/gateway/Gateway.cgi?GWVersion=2&SrcAuth=Alerting&SrcApp=Alerting&DestApp=WOS&DestLinkType=FullRecord;KeyUT=000253512400021}}
71
72 @article{PhysRevB.59.3527,
73 Author = {Qi, Yue and \c{C}a\v{g}in, Tahir and Kimura, Yoshitaka and {Goddard III}, William A.},
74 Date-Added = {2010-07-13 11:44:08 -0400},
75 Date-Modified = {2010-07-13 11:44:08 -0400},
76 Doi = {10.1103/PhysRevB.59.3527},
77 Journal = {Phys. Rev. B},
78 Local-Url = {file://localhost/Users/charles/Documents/Papers/Qi/1999.pdf},
79 Month = {Feb},
80 Number = {5},
81 Numpages = {6},
82 Pages = {3527-3533},
83 Publisher = {American Physical Society},
84 Title = {Molecular-dynamics simulations of glass formation and crystallization in binary liquid metals:\quad{}{C}u-{A}g and {C}u-{N}i},
85 Volume = {59},
86 Year = {1999},
87 Bdsk-Url-1 = {http://dx.doi.org/10.1103/PhysRevB.59.3527}}
88
89 @article{Medasani:2007uq,
90 Abstract = {We employ first-principles and empirical computational methods to study the surface energy and surface stress of silver nanoparticles. The structures, cohesive energies, and lattice contractions of spherical Ag nanoclusters in the size range 0.5-5.5 nm are analyzed using two different theoretical approaches: an ab initio density functional pseudopotential technique combined with the generalized gradient approximation and the embedded atom method. The surface energies and stresses obtained via the embedded atom method are found to be in good agreement with those predicted by the gradient-corrected ab initio density functional formalism. We estimate the surface energy of Ag nanoclusters to be in the range of 1.0-2.2 J/m(2). Our values are close to the bulk surface energy of silver, but are significantly lower than the recently reported value of 7.2 J/m(2) for free Ag nanoparticles derived from the Kelvin equation.},
91 Author = {Medasani, Bharat and Park, Young Ho and Vasiliev, Igor},
92 Date-Added = {2010-07-13 11:43:15 -0400},
93 Date-Modified = {2010-07-13 11:43:15 -0400},
94 Doi = {ARTN 235436},
95 Journal = {Phys. Rev. B},
96 Local-Url = {file://localhost/Users/charles/Documents/Papers/PhysRevB_75_235436.pdf},
97 Title = {Theoretical study of the surface energy, stress, and lattice contraction of silver nanoparticles},
98 Volume = {75},
99 Year = {2007},
100 Bdsk-Url-1 = {http://dx.doi.org/235436}}
101
102 @article{Wang:2005qy,
103 Abstract = {The surface structures of cubo-octahedral Pt-Mo nanoparticles have been investigated using the Monte Carlo method and modified embedded atom method potentials that we developed for Pt-Mo alloys. The cubo-octahedral Pt-Mo nanoparticles are constructed with disordered fcc configurations, with sizes from 2.5 to 5.0 nm, and with Pt concentrations from 60 to 90 atom \%. The equilibrium Pt-Mo nanoparticle configurations were generated through Monte Carlo simulations allowing both atomic displacements and element exchanges at 600 K. We predict that the Pt atoms weakly segregate to the surfaces of such nanoparticles. The Pt concentrations in the surface are calculated to be 5-14 atom \% higher than the Pt concentrations of the nanoparticles. Moreover, the Pt atoms preferentially segregate to the facet sites of the surface, while the Pt and Mo atoms tend to alternate along the edges and vertexes of these nanoparticles. We found that decreasing the size or increasing the Pt concentration leads to higher Pt concentrations but fewer Pt-Mo pairs in the Pt-Mo nanoparticle surfaces.},
104 Author = {Wang, GF and Van Hove, MA and Ross, PN and Baskes, MI},
105 Date-Added = {2010-07-13 11:42:50 -0400},
106 Date-Modified = {2010-07-13 11:42:50 -0400},
107 Doi = {DOI 10.1021/jp050116n},
108 Journal = {J. Phys. Chem. B},
109 Pages = {11683-11692},
110 Title = {Surface structures of cubo-octahedral Pt-Mo catalyst nanoparticles from Monte Carlo simulations},
111 Volume = {109},
112 Year = {2005},
113 Bdsk-Url-1 = {http://dx.doi.org/10.1021/jp050116n}}
114
115 @article{Chui:2003fk,
116 Abstract = {Molecular dynamics simulations of a platinum nanocluster consisting 250 atoms were performed at different temperatures between 70 K and 298 K. The semi-empirical, many-body Sutton-Chen (SC) potential was used to model the interatomic interaction in the metallic system. Regions of core or bulk-like atoms and surface atoms can be defined from analyses of structures, atomic coordination, and the local density function of atoms as defined in the SC potential. The core atoms in the nanoparticle behave as bulk-like metal atoms with a predominant face centered cubic (fcc) packing. The interface between surface atoms and core atoms is marked by a peak in the local density function and corresponds to near surface atoms. The near surface atoms and surface atoms prefer a hexagonal closed packing (hcp). The temperature and size effects on structures of the nanoparticle and the dynamics of the surface region and the core region are discussed.},
117 Author = {Chui, YH and Chan, KY},
118 Date-Added = {2010-07-13 11:42:32 -0400},
119 Date-Modified = {2010-07-13 11:42:32 -0400},
120 Doi = {DOI 10.1039/b302122j},
121 Journal = {Phys. Chem. Chem. Phys.},
122 Pages = {2869-2874},
123 Title = {Analyses of surface and core atoms in a platinum nanoparticle},
124 Volume = {5},
125 Year = {2003},
126 Bdsk-Url-1 = {http://dx.doi.org/10.1039/b302122j}}
127
128 @article{Sankaranarayanan:2005lr,
129 Abstract = {Bimetallic nanoclusters are of interest because of their utility in catalysis and sensors, The thermal characteristics of bimetallic Pt-Pd nanoclusters of different sizes and compositions were investigated through molecular dynamics simulations using quantum Sutton-Chen (QSC) many-body potentials, Monte Carlo simulations employing the bond order simulation model were used to generate minimum energy configurations, which were utilized as the starting point for molecular dynamics simulations. The calculated initial configurations of the Pt-Pd system consisted of surface segregated Pd atoms and a Pt-rich core, Melting characteristics were studied by following the changes in potential energy and heat capacity as functions of temperature, Structural changes accompanying the thermal evolution were studied by the bond order parameter method. The Pt-Pd clusters exhibited a two-stage melting: surface melting of the external Pd atoms followed by homogeneous melting of the Pt core. These transitions were found to depend on the composition and size of the nanocluster. Melting temperatures of the nanoclusters were found to be much lower than those of bulk Pt and Pd. Bulk melting temperatures of Pd and Pt simulated using periodic boundary conditions compare well with experimental values, thus providing justification for the use of QSC potentials in these simulations. Deformation parameters were calculated to characterize the structural evolution resulting from diffusion of Pd and Pt atoms, The results indicate that in Pd-Pt clusters, Pd atoms prefer to remain at the surface even after melting. In addition, Pt also tends to diffuse to the surface after melting due to reduction of its surface energy with temperature. This mixing pattern is different from those reported in some of the earlier Studies on melting of bimetallics.},
130 Author = {Sankaranarayanan, SKRS and Bhethanabotla, VR and Joseph, B},
131 Date-Added = {2010-07-13 11:42:13 -0400},
132 Date-Modified = {2010-07-13 11:42:13 -0400},
133 Doi = {ARTN 195415},
134 Journal = {Phys. Rev. B},
135 Title = {Molecular dynamics simulation study of the melting of Pd-Pt nanoclusters},
136 Volume = {71},
137 Year = {2005},
138 Bdsk-Url-1 = {http://dx.doi.org/195415}}
139
140 @article{Vardeman-II:2001jn,
141 Author = {C.~F. {Vardeman II} and J.~D. Gezelter},
142 Date-Added = {2010-07-13 11:41:50 -0400},
143 Date-Modified = {2010-07-13 11:41:50 -0400},
144 Journal = {J. Phys. Chem. A},
145 Local-Url = {file://localhost/Users/charles/Documents/Papers/Vardeman%20II/2001.pdf},
146 Number = {12},
147 Pages = {2568},
148 Title = {Comparing models for diffusion in supercooled liquids: The eutectic composition of the {A}g-{C}u alloy},
149 Volume = {105},
150 Year = {2001}}
151
152 @article{ShibataT._ja026764r,
153 Author = {Shibata, T. and Bunker, B.A. and Zhang, Z. and Meisel, D. and Vardeman, C.F. and Gezelter, J.D.},
154 Date-Added = {2010-07-13 11:41:36 -0400},
155 Date-Modified = {2010-07-13 11:41:36 -0400},
156 Journal = {J. Amer. Chem. Soc.},
157 Local-Url = {file://localhost/Users/charles/Documents/Papers/ja026764r.pdf},
158 Number = {40},
159 Pages = {11989-11996},
160 Title = {Size-Dependent Spontaneous Alloying of {A}u-{A}g Nanoparticles},
161 Url = {http://dx.doi.org/10.1021/ja026764r},
162 Volume = {124},
163 Year = {2002},
164 Bdsk-Url-1 = {http://dx.doi.org/10.1021/ja026764r}}
165
166 @article{Chen90,
167 Author = {A.~P. Sutton and J. Chen},
168 Date-Added = {2010-07-13 11:40:48 -0400},
169 Date-Modified = {2010-07-13 11:40:48 -0400},
170 Journal = {Phil. Mag. Lett.},
171 Pages = {139-146},
172 Title = {Long-Range Finnis Sinclair Potentials},
173 Volume = 61,
174 Year = {1990}}
175
176 @article{PhysRevB.33.7983,
177 Author = {Foiles, S. M. and Baskes, M. I. and Daw, M. S.},
178 Date-Added = {2010-07-13 11:40:28 -0400},
179 Date-Modified = {2010-07-13 11:40:28 -0400},
180 Doi = {10.1103/PhysRevB.33.7983},
181 Journal = {Phys. Rev. B},
182 Local-Url = {file://localhost/Users/charles/Documents/Papers/p7983_1.pdf},
183 Month = {Jun},
184 Number = {12},
185 Numpages = {8},
186 Pages = {7983-7991},
187 Publisher = {American Physical Society},
188 Title = {Embedded-atom-method functions for the fcc metals {C}u, {A}g, {A}u, {N}i, {P}d, {P}t, and their alloys},
189 Volume = {33},
190 Year = {1986},
191 Bdsk-Url-1 = {http://dx.doi.org/10.1103/PhysRevB.33.7983}}
192
193 @article{hoover85,
194 Author = {W.~G. Hoover},
195 Date-Added = {2010-07-13 11:24:30 -0400},
196 Date-Modified = {2010-07-13 11:24:30 -0400},
197 Journal = pra,
198 Pages = 1695,
199 Title = {Canonical dynamics: Equilibrium phase-space distributions},
200 Volume = 31,
201 Year = 1985}
202
203 @article{melchionna93,
204 Author = {S. Melchionna and G. Ciccotti and B.~L. Holian},
205 Date-Added = {2010-07-13 11:22:17 -0400},
206 Date-Modified = {2010-07-13 11:22:17 -0400},
207 Journal = {Mol. Phys.},
208 Pages = {533-544},
209 Title = {Hoover {\sc npt} dynamics for systems varying in shape and size},
210 Volume = 78,
211 Year = 1993}
212
213 @misc{openmd,
214 Author = {J. Daniel Gezelter and Shenyu Kuang and James Marr and Kelsey Stocker and Chunlei Li and Charles F. Vardeman and Teng Lin and Christopher J. Fennell and Xiuquan Sun and Kyle Daily and Yang Zheng and Matthew A. Meineke},
215 Date-Added = {2010-07-13 11:16:00 -0400},
216 Date-Modified = {2010-07-19 16:27:45 -0400},
217 Howpublished = {Available at {\tt http://openmd.net}},
218 Title = {{OpenMD}}}
219
220 @inbook{AshcroftMermin,
221 Author = {N.~David Mermin and Neil W. Ashcroft},
222 Date-Added = {2010-07-12 14:26:49 -0400},
223 Date-Modified = {2010-07-22 13:37:20 -0400},
224 Pages = {21},
225 Publisher = {Brooks Cole},
226 Title = {Solid State Physics},
227 Year = {1976}}
228
229 @book{WagnerKruse,
230 Address = {Berlin},
231 Author = {W. Wagner and A. Kruse},
232 Date-Added = {2010-07-12 14:10:29 -0400},
233 Date-Modified = {2010-07-12 14:13:44 -0400},
234 Publisher = {Springer-Verlag},
235 Title = {Properties of Water and Steam, the Industrial Standard IAPWS-IF97 for the Thermodynamic Properties and Supplementary Equations for Other Properties},
236 Year = {1998}}
237
238 @article{ISI:000266247600008,
239 Abstract = {Temperature dependence of viscosity of butyl-3-methylimidazolium
240 hexafluorophosphate is investigated by non-equilibrium molecular
241 dynamics simulations with cosine-modulated force in the temperature
242 range from 360 to 480K. It is shown that this method is able to
243 correctly predict the shear viscosity. The simulation setting and
244 choice of the force field are discussed in detail. The all-atom force
245 field exhibits a bad convergence and the shear viscosity is
246 overestimated, while the simple united atom model predicts the kinetics
247 very well. The results are compared with the equilibrium molecular
248 dynamics simulations. The relationship between the diffusion
249 coefficient and viscosity is examined by means of the hydrodynamic
250 radii calculated from the Stokes-Einstein equation and the solvation
251 properties are discussed.},
252 Address = {4 PARK SQUARE, MILTON PARK, ABINGDON OX14 4RN, OXON, ENGLAND},
253 Affiliation = {Kolafa, J (Reprint Author), Prague Inst Chem Technol, Dept Phys Chem, CR-16628 Prague, Czech Republic. {[}Picalek, Jan; Kolafa, Jiri] Prague Inst Chem Technol, Dept Phys Chem, CR-16628 Prague, Czech Republic.},
254 Author = {Picalek, Jan and Kolafa, Jiri},
255 Author-Email = {jiri.kolafa@vscht.cz},
256 Date-Added = {2010-04-16 13:19:12 -0400},
257 Date-Modified = {2010-04-16 13:19:12 -0400},
258 Doc-Delivery-Number = {448FD},
259 Doi = {10.1080/08927020802680703},
260 Funding-Acknowledgement = {Czech Science Foundation {[}203/07/1006]; Czech Ministry of Education {[}LC512]},
261 Funding-Text = {We gratefully acknowledge a support from the Czech Science Foundation (project 203/07/1006) and the computing facilities from the Czech Ministry of Education (Center for Biomolecules and Complex Molecular Systems, project LC512).},
262 Issn = {0892-7022},
263 Journal = {Mol. Simul.},
264 Journal-Iso = {Mol. Simul.},
265 Keywords = {room temperature ionic liquids; viscosity; non-equilibrium molecular dynamics; solvation; imidazolium},
266 Keywords-Plus = {1-N-BUTYL-3-METHYLIMIDAZOLIUM HEXAFLUOROPHOSPHATE; PHYSICOCHEMICAL PROPERTIES; COMPUTER-SIMULATION; PHYSICAL-PROPERTIES; IMIDAZOLIUM CATION; FORCE-FIELD; AB-INITIO; TEMPERATURE; CHLORIDE; CONDUCTIVITY},
267 Language = {English},
268 Number = {8},
269 Number-Of-Cited-References = {50},
270 Pages = {685-690},
271 Publisher = {TAYLOR \& FRANCIS LTD},
272 Subject-Category = {Chemistry, Physical; Physics, Atomic, Molecular \& Chemical},
273 Times-Cited = {2},
274 Title = {Shear viscosity of ionic liquids from non-equilibrium molecular dynamics simulation},
275 Type = {Article},
276 Unique-Id = {ISI:000266247600008},
277 Volume = {35},
278 Year = {2009},
279 Bdsk-Url-1 = {http://dx.doi.org/10.1080/08927020802680703%7D}}
280
281 @article{Vasquez:2004fk,
282 Abstract = {A method for fast calculation of viscosity from molecular dynamics simulation is revisited. The method consists of using a steady-state periodic perturbation. A methodology to choose the amplitude of the external perturbation, which is one of the major practical issues in the original technique of Gosling et al. {$[$}Mol. Phys. 26: 1475 (1973){$]$} is proposed. The amplitude of the perturbation required for fast caculations and the viscosity values for wide ranges of temperature and density of the Lennard-Jones (LJ) model fluid are reported. The viscosity results are in agreement with recent LJ viscosity calculations. Additionally, the simulations demonstrate that the proposed approach is suitable to efficiently generate viscosity data of good quality.},
283 Author = {Vasquez, V. R. and Macedo, E. A. and Zabaloy, M. S.},
284 Date = {2004/11/02/},
285 Date-Added = {2010-04-16 13:18:48 -0400},
286 Date-Modified = {2010-04-16 13:18:48 -0400},
287 Day = {02},
288 Journal = {Int. J. Thermophys.},
289 M3 = {10.1007/s10765-004-7736-3},
290 Month = {11},
291 Number = {6},
292 Pages = {1799--1818},
293 Title = {Lennard-Jones Viscosities in Wide Ranges of Temperature and Density: Fast Calculations Using a Steady--State Periodic Perturbation Method},
294 Ty = {JOUR},
295 Url = {http://dx.doi.org/10.1007/s10765-004-7736-3},
296 Volume = {25},
297 Year = {2004},
298 Bdsk-Url-1 = {http://dx.doi.org/10.1007/s10765-004-7736-3}}
299
300 @article{hess:209,
301 Author = {Berk Hess},
302 Date-Added = {2010-04-16 12:37:37 -0400},
303 Date-Modified = {2010-04-16 12:37:37 -0400},
304 Doi = {10.1063/1.1421362},
305 Journal = {J. Chem. Phys.},
306 Keywords = {viscosity; molecular dynamics method; liquid theory; shear flow},
307 Number = {1},
308 Pages = {209-217},
309 Publisher = {AIP},
310 Title = {Determining the shear viscosity of model liquids from molecular dynamics simulations},
311 Url = {http://link.aip.org/link/?JCP/116/209/1},
312 Volume = {116},
313 Year = {2002},
314 Bdsk-Url-1 = {http://link.aip.org/link/?JCP/116/209/1},
315 Bdsk-Url-2 = {http://dx.doi.org/10.1063/1.1421362}}
316
317 @article{backer:154503,
318 Author = {J. A. Backer and C. P. Lowe and H. C. J. Hoefsloot and P. D. Iedema},
319 Date-Added = {2010-04-16 12:37:37 -0400},
320 Date-Modified = {2010-04-16 12:37:37 -0400},
321 Doi = {10.1063/1.1883163},
322 Eid = {154503},
323 Journal = {J. Chem. Phys.},
324 Keywords = {Poiseuille flow; flow simulation; Lennard-Jones potential; viscosity; boundary layers; computational fluid dynamics},
325 Number = {15},
326 Numpages = {6},
327 Pages = {154503},
328 Publisher = {AIP},
329 Title = {Poiseuille flow to measure the viscosity of particle model fluids},
330 Url = {http://link.aip.org/link/?JCP/122/154503/1},
331 Volume = {122},
332 Year = {2005},
333 Bdsk-Url-1 = {http://link.aip.org/link/?JCP/122/154503/1},
334 Bdsk-Url-2 = {http://dx.doi.org/10.1063/1.1883163}}
335
336 @article{daivis:541,
337 Author = {Peter J. Daivis and Denis J. Evans},
338 Date-Added = {2010-04-16 12:05:36 -0400},
339 Date-Modified = {2010-04-16 12:05:36 -0400},
340 Doi = {10.1063/1.466970},
341 Journal = {J. Chem. Phys.},
342 Keywords = {SHEAR; DECANE; FLOW MODELS; VOLUME; PRESSURE; NONEQUILIBRIUM; MOLECULAR DYNAMICS CALCULATIONS; COMPARATIVE EVALUATIONS; SIMULATION; STRAIN RATE; VISCOSITY; KUBO FORMULA},
343 Number = {1},
344 Pages = {541-547},
345 Publisher = {AIP},
346 Title = {Comparison of constant pressure and constant volume nonequilibrium simulations of sheared model decane},
347 Url = {http://link.aip.org/link/?JCP/100/541/1},
348 Volume = {100},
349 Year = {1994},
350 Bdsk-Url-1 = {http://link.aip.org/link/?JCP/100/541/1},
351 Bdsk-Url-2 = {http://dx.doi.org/10.1063/1.466970}}
352
353 @article{mondello:9327,
354 Author = {Maurizio Mondello and Gary S. Grest},
355 Date-Added = {2010-04-16 12:05:36 -0400},
356 Date-Modified = {2010-04-16 12:05:36 -0400},
357 Doi = {10.1063/1.474002},
358 Journal = {J. Chem. Phys.},
359 Keywords = {organic compounds; viscosity; digital simulation; molecular dynamics method},
360 Number = {22},
361 Pages = {9327-9336},
362 Publisher = {AIP},
363 Title = {Viscosity calculations of [bold n]-alkanes by equilibrium molecular dynamics},
364 Url = {http://link.aip.org/link/?JCP/106/9327/1},
365 Volume = {106},
366 Year = {1997},
367 Bdsk-Url-1 = {http://link.aip.org/link/?JCP/106/9327/1},
368 Bdsk-Url-2 = {http://dx.doi.org/10.1063/1.474002}}
369
370 @article{ISI:A1988Q205300014,
371 Address = {ONE GUNDPOWDER SQUARE, LONDON, ENGLAND EC4A 3DE},
372 Affiliation = {VOGELSANG, R (Reprint Author), RUHR UNIV BOCHUM,UNIV STR 150,D-4630 BOCHUM,FED REP GER. UNIV DUISBURG,THERMODYNAM,D-4100 DUISBURG,FED REP GER.},
373 Author = {Vogelsang, R and Hoheisel, G and Luckas, M},
374 Date-Added = {2010-04-14 16:20:24 -0400},
375 Date-Modified = {2010-04-14 16:20:24 -0400},
376 Doc-Delivery-Number = {Q2053},
377 Issn = {0026-8976},
378 Journal = {Mol. Phys.},
379 Journal-Iso = {Mol. Phys.},
380 Language = {English},
381 Month = {AUG 20},
382 Number = {6},
383 Number-Of-Cited-References = {14},
384 Pages = {1203-1213},
385 Publisher = {TAYLOR \& FRANCIS LTD},
386 Subject-Category = {Physics, Atomic, Molecular \& Chemical},
387 Times-Cited = {12},
388 Title = {SHEAR VISCOSITY AND THERMAL-CONDUCTIVITY OF THE LENNARD-JONES LIQUID COMPUTED USING MOLECULAR-DYNAMICS AND PREDICTED BY A MEMORY FUNCTION MODEL FOR A LARGE NUMBER OF STATES},
389 Type = {Article},
390 Unique-Id = {ISI:A1988Q205300014},
391 Volume = {64},
392 Year = {1988}}
393
394 @article{ISI:000261835100054,
395 Abstract = {Transport properties of liquid methanol and ethanol are predicted by
396 molecular dynamics simulation. The molecular models for the alcohols
397 are rigid, nonpolarizable, and of united-atom type. They were developed
398 in preceding work using experimental vapor-liquid equilibrium data
399 only. Self- and Maxwell-Stefan diffusion coefficients as well as the
400 shear viscosity of methanol, ethanol, and their binary mixture are
401 determined using equilibrium molecular dynamics and the Green-Kubo
402 formalism. Nonequilibrium molecular dynamics is used for predicting the
403 thermal conductivity of the two pure substances. The transport
404 properties of the fluids are calculated over a wide temperature range
405 at ambient pressure and compared with experimental and simulation data
406 from the literature. Overall, a very good agreement with the experiment
407 is found. For instance, the self-diffusion coefficient and the shear
408 viscosity are predicted with average deviations of less than 8\% for
409 the pure alcohols and 12\% for the mixture. The predicted thermal
410 conductivity agrees on average within 5\% with the experimental data.
411 Additionally, some velocity and shear viscosity autocorrelation
412 functions are presented and discussed. Radial distribution functions
413 for ethanol are also presented. The predicted excess volume, excess
414 enthalpy, and the vapor-liquid equilibrium of the binary mixture
415 methanol + ethanol are assessed and agree well with experimental data.},
416 Address = {1155 16TH ST, NW, WASHINGTON, DC 20036 USA},
417 Affiliation = {Vrabec, J (Reprint Author), Univ Stuttgart, Inst Thermodynam \& Thermal Proc Engn, D-70550 Stuttgart, Germany. {[}Vrabec, Jadran] Univ Stuttgart, Inst Thermodynam \& Thermal Proc Engn, D-70550 Stuttgart, Germany. {[}Guevara-Carrion, Gabriela; Hasse, Hans] Univ Kaiserslautern, Lab Engn Thermodynam, D-67663 Kaiserslautern, Germany. {[}Nieto-Draghi, Carlos] Inst Francais Petr, F-92852 Rueil Malmaison, France.},
418 Author = {Guevara-Carrion, Gabriela and Nieto-Draghi, Carlos and Vrabec, Jadran and Hasse, Hans},
419 Author-Email = {vrabec@itt.uni-stuttgart.de},
420 Date-Added = {2010-04-14 15:43:29 -0400},
421 Date-Modified = {2010-04-14 15:43:29 -0400},
422 Doc-Delivery-Number = {385SY},
423 Doi = {10.1021/jp805584d},
424 Issn = {1520-6106},
425 Journal = {J. Phys. Chem. B},
426 Journal-Iso = {J. Phys. Chem. B},
427 Keywords-Plus = {STEFAN DIFFUSION-COEFFICIENTS; MONTE-CARLO CALCULATIONS; ATOM FORCE-FIELD; SELF-DIFFUSION; DYNAMICS SIMULATION; PHASE-EQUILIBRIA; LIQUID METHANOL; TEMPERATURE-DEPENDENCE; COMPUTER-SIMULATION; MONOHYDRIC ALCOHOLS},
428 Language = {English},
429 Month = {DEC 25},
430 Number = {51},
431 Number-Of-Cited-References = {86},
432 Pages = {16664-16674},
433 Publisher = {AMER CHEMICAL SOC},
434 Subject-Category = {Chemistry, Physical},
435 Times-Cited = {5},
436 Title = {Prediction of Transport Properties by Molecular Simulation: Methanol and Ethanol and Their Mixture},
437 Type = {Article},
438 Unique-Id = {ISI:000261835100054},
439 Volume = {112},
440 Year = {2008},
441 Bdsk-Url-1 = {http://dx.doi.org/10.1021/jp805584d%7D}}
442
443 @article{ISI:000258460400020,
444 Abstract = {Nonequilibrium molecular dynamics simulations with the nonpolarizable
445 SPC/E (Berendsen et al., J. Phys. Chem. 1987, 91, 6269) and the
446 polarizable COS/G2 (Yu and van Gunsteren, J. Chem. Phys. 2004, 121,
447 9549) force fields have been employed to calculate the thermal
448 conductivity and other associated properties of methane hydrate over a
449 temperature range from 30 to 260 K. The calculated results are compared
450 to experimental data over this same range. The values of the thermal
451 conductivity calculated with the COS/G2 model are closer to the
452 experimental values than are those calculated with the nonpolarizable
453 SPC/E model. The calculations match the temperature trend in the
454 experimental data at temperatures below 50 K; however, they exhibit a
455 slight decrease in thermal conductivity at higher temperatures in
456 comparison to an opposite trend in the experimental data. The
457 calculated thermal conductivity values are found to be relatively
458 insensitive to the occupancy of the cages except at low (T <= 50 K)
459 temperatures, which indicates that the differences between the two
460 lattice structures may have a more dominant role than generally thought
461 in explaining the low thermal conductivity of methane hydrate compared
462 to ice Ih. The introduction of defects into the water lattice is found
463 to cause a reduction in the thermal conductivity but to have a
464 negligible impact on its temperature dependence.},
465 Address = {1155 16TH ST, NW, WASHINGTON, DC 20036 USA},
466 Affiliation = {Jordan, KD (Reprint Author), US DOE, Natl Energy Technol Lab, POB 10940, Pittsburgh, PA 15236 USA. {[}Jiang, Hao; Myshakin, Evgeniy M.; Jordan, Kenneth D.; Warzinski, Robert P.] US DOE, Natl Energy Technol Lab, Pittsburgh, PA 15236 USA. {[}Jiang, Hao; Jordan, Kenneth D.] Univ Pittsburgh, Dept Chem, Pittsburgh, PA 15260 USA. {[}Jiang, Hao; Jordan, Kenneth D.] Univ Pittsburgh, Ctr Mol \& Mat Simulat, Pittsburgh, PA 15260 USA. {[}Myshakin, Evgeniy M.] Parsons Project Serv Inc, South Pk, PA 15129 USA.},
467 Author = {Jiang, Hao and Myshakin, Evgeniy M. and Jordan, Kenneth D. and Warzinski, Robert P.},
468 Date-Added = {2010-04-14 15:38:14 -0400},
469 Date-Modified = {2010-04-14 15:38:14 -0400},
470 Doc-Delivery-Number = {337UG},
471 Doi = {10.1021/jp802942v},
472 Funding-Acknowledgement = {E.M.M. ; National Energy Technology Laboratory's Office of Research and Development {[}41817.660.01.03]; ORISE Part-Time Faculty Program ; {[}DE-AM26-04NT41817]; {[}41817.606.06.03]},
473 Funding-Text = {We thank Drs. John Tse, Niall English, and Alan McGaughey for their comments. H.J. and K.D.J. performed this work under Contract DE-AM26-04NT41817, Subtask 41817.606.06.03, and E.M.M. performed this work under the same contract, Subtask 41817.660.01.03, in support of the National Energy Technology Laboratory's Office of Research and Development. K.D.J. was also supported at NETL by the ORISE Part-Time Faculty Program during the early stages of this work.},
474 Issn = {1520-6106},
475 Journal = {J. Phys. Chem. B},
476 Journal-Iso = {J. Phys. Chem. B},
477 Keywords-Plus = {LIQUID WATER; CLATHRATE HYDRATE; HEAT-CAPACITY; FORCE-FIELDS; ICE; ANHARMONICITY; SUMMATION; MODELS; SILICA},
478 Language = {English},
479 Month = {AUG 21},
480 Number = {33},
481 Number-Of-Cited-References = {51},
482 Pages = {10207-10216},
483 Publisher = {AMER CHEMICAL SOC},
484 Subject-Category = {Chemistry, Physical},
485 Times-Cited = {8},
486 Title = {Molecular dynamics Simulations of the thermal conductivity of methane hydrate},
487 Type = {Article},
488 Unique-Id = {ISI:000258460400020},
489 Volume = {112},
490 Year = {2008},
491 Bdsk-Url-1 = {http://dx.doi.org/10.1021/jp802942v%7D}}
492
493 @article{ISI:000184808400018,
494 Abstract = {A new non-equilibrium molecular dynamics algorithm is presented based
495 on the original work of Willer-Plathe, (1997, J. chem. Phys., 106,
496 6082), for the non-equilibrium simulation of heat transport maintaining
497 fixed the total momentum as well as the total energy of the system. The
498 presented scheme preserves these properties but, unlike the original
499 algorithm, is able to deal with multicomponent systems, that is with
500 particles of different mass independently of their relative
501 concentration. The main idea behind the new procedure is to consider an
502 exchange of momentum and energy between the particles in the hot and
503 cold regions, to maintain the non-equilibrium conditions, as if they
504 undergo a hypothetical elastic collision. The new algorithm can also be
505 employed in multicomponent systems for molecular fluids and in a wide
506 range of thermodynamic conditions.},
507 Address = {4 PARK SQUARE, MILTON PARK, ABINGDON OX14 4RN, OXON, ENGLAND},
508 Affiliation = {Nieto-Draghi, C (Reprint Author), Univ Rovira \& Virgili, ETSEQ, Dept Engn Quim, Avda Paisos Catalans 26, Tarragona 43007, Spain. Univ Rovira \& Virgili, ETSEQ, Dept Engn Quim, Tarragona 43007, Spain.},
509 Author = {Nieto-Draghi, C and Avalos, JB},
510 Date-Added = {2010-04-14 12:48:08 -0400},
511 Date-Modified = {2010-04-14 12:48:08 -0400},
512 Doc-Delivery-Number = {712QM},
513 Doi = {10.1080/0026897031000154338},
514 Issn = {0026-8976},
515 Journal = {Mol. Phys.},
516 Journal-Iso = {Mol. Phys.},
517 Keywords-Plus = {BINARY-LIQUID MIXTURES; THERMAL-CONDUCTIVITY; MATTER TRANSPORT; WATER},
518 Language = {English},
519 Month = {JUL 20},
520 Number = {14},
521 Number-Of-Cited-References = {20},
522 Pages = {2303-2307},
523 Publisher = {TAYLOR \& FRANCIS LTD},
524 Subject-Category = {Physics, Atomic, Molecular \& Chemical},
525 Times-Cited = {13},
526 Title = {Non-equilibrium momentum exchange algorithm for molecular dynamics simulation of heat flow in multicomponent systems},
527 Type = {Article},
528 Unique-Id = {ISI:000184808400018},
529 Volume = {101},
530 Year = {2003},
531 Bdsk-Url-1 = {http://dx.doi.org/10.1080/0026897031000154338%7D}}
532
533 @article{Bedrov:2000-1,
534 Abstract = {The thermal conductivity of liquid
535 octahydro-1,3,5,7-tetranitro-1,3,5,7-tetrazocine (HMX) has been
536 determined from imposed heat flux non-equilibrium molecular dynamics
537 (NEMD) simulations using a previously published quantum chemistry-based
538 atomistic potential. The thermal conductivity was determined in the
539 temperature domain 550 less than or equal to T less than or equal to
540 800 K, which corresponds approximately to the existence limits of the
541 liquid phase of HMX at atmospheric pressure. The NEMD predictions,
542 which comprise the first reported values for thermal conductivity of
543 HMX liquid, were found to be consistent with measured values for
544 crystalline HMX. The thermal conductivity of liquid HMX was found to
545 exhibit a much weaker temperature dependence than the shear viscosity
546 and self-diffusion coefficients. (C) 2000 Elsevier Science B.V. All
547 rights reserved.},
548 Address = {PO BOX 211, 1000 AE AMSTERDAM, NETHERLANDS},
549 Affiliation = {Bedrov, D (Reprint Author), Univ Utah, Dept Mat Sci \& Engn, 122 S Cent Campus Dr,Room 304, Salt Lake City, UT 84112 USA. Univ Utah, Dept Mat Sci \& Engn, Salt Lake City, UT 84112 USA. Univ Utah, Dept Chem \& Fuels Engn, Salt Lake City, UT 84112 USA. Univ Calif Los Alamos Natl Lab, Div Theoret, Los Alamos, NM 87545 USA.},
550 Author = {Bedrov, D and Smith, GD and Sewell, TD},
551 Date-Added = {2010-04-14 12:26:59 -0400},
552 Date-Modified = {2010-04-14 12:27:52 -0400},
553 Doc-Delivery-Number = {330PF},
554 Issn = {0009-2614},
555 Journal = {Chem. Phys. Lett.},
556 Journal-Iso = {Chem. Phys. Lett.},
557 Keywords-Plus = {FORCE-FIELD},
558 Language = {English},
559 Month = {JUN 30},
560 Number = {1-3},
561 Number-Of-Cited-References = {17},
562 Pages = {64-68},
563 Publisher = {ELSEVIER SCIENCE BV},
564 Subject-Category = {Chemistry, Physical; Physics, Atomic, Molecular \& Chemical},
565 Times-Cited = {19},
566 Title = {Thermal conductivity of liquid octahydro-1,3,5,7-tetranitro-1,3,5,7-tetrazocine (HMX) from molecular dynamics simulations},
567 Type = {Article},
568 Unique-Id = {ISI:000087969900011},
569 Volume = {324},
570 Year = {2000}}
571
572 @article{ISI:000258840700015,
573 Abstract = {By using the embedded-atom method (EAM), a series of molecular dynamics
574 (MD) simulations are carried out to calculate the viscosity and
575 self-diffusion coefficient of liquid copper from the normal to the
576 undercooled states. The simulated results are in reasonable agreement
577 with the experimental values available above the melting temperature
578 that is also predicted from a solid-liquid-solid sandwich structure.
579 The relationship between the viscosity and the self-diffusion
580 coefficient is evaluated. It is found that the Stokes-Einstein and
581 Sutherland-Einstein relations qualitatively describe this relationship
582 within the simulation temperature range. However, the predicted
583 constant from MD simulation is close to 1/(3 pi), which is larger than
584 the constants of the Stokes-Einstein and Sutherland-Einstein relations.},
585 Address = {233 SPRING ST, NEW YORK, NY 10013 USA},
586 Affiliation = {Chen, M (Reprint Author), Tsinghua Univ, Dept Engn Mech, Beijing 100084, Peoples R China. {[}Han, X. J.; Chen, M.; Lue, Y. J.] Tsinghua Univ, Dept Engn Mech, Beijing 100084, Peoples R China.},
587 Author = {Han, X. J. and Chen, M. and Lue, Y. J.},
588 Author-Email = {mchen@tsinghua.edu.cn},
589 Date-Added = {2010-04-14 12:00:38 -0400},
590 Date-Modified = {2010-04-14 12:00:38 -0400},
591 Doc-Delivery-Number = {343GH},
592 Doi = {10.1007/s10765-008-0489-7},
593 Funding-Acknowledgement = {China Postdoctoral Science Foundation ; National Natural Science Foundation of China {[}50395101, 50371043]},
594 Funding-Text = {This work was financially supported by China Postdoctoral Science Foundation and the National Natural Science Foundation of China under grant Nos. of 50395101 and 50371043. The computations are carried out at the Tsinghua National Laboratory for Information Science and Technology, China. The authors are grateful to Mr. D. Q. Yu for valuable discussions.},
595 Issn = {0195-928X},
596 Journal = {Int. J. Thermophys.},
597 Journal-Iso = {Int. J. Thermophys.},
598 Keywords = {copper; molecular simulation; self-diffusion coefficient; viscosity; undercooled},
599 Keywords-Plus = {EMBEDDED-ATOM MODEL; THERMOPHYSICAL PROPERTIES; COMPUTER-SIMULATION; TRANSITION-METALS; SHEAR VISCOSITY; ALLOYS; TEMPERATURE; DIFFUSION; BINDING; SURFACE},
600 Language = {English},
601 Month = {AUG},
602 Number = {4},
603 Number-Of-Cited-References = {39},
604 Pages = {1408-1421},
605 Publisher = {SPRINGER/PLENUM PUBLISHERS},
606 Subject-Category = {Thermodynamics; Chemistry, Physical; Mechanics; Physics, Applied},
607 Times-Cited = {2},
608 Title = {Transport properties of undercooled liquid copper: A molecular dynamics study},
609 Type = {Article},
610 Unique-Id = {ISI:000258840700015},
611 Volume = {29},
612 Year = {2008},
613 Bdsk-Url-1 = {http://dx.doi.org/10.1007/s10765-008-0489-7%7D}}
614
615 @article{Muller-Plathe:2008,
616 Abstract = {Reverse nonequilibrium molecular dynamics and equilibrium molecular
617 dynamics simulations were carried out to compute the shear viscosity of
618 the pure ionic liquid system {[}bmim]{[}PF6] at 300 K. The two methods
619 yielded consistent results which were also compared to experiments. The
620 results showed that the reverse nonequilibrium molecular dynamics
621 (RNEMD) methodology can successfully be applied to computation of
622 highly viscous ionic liquids. Moreover, this study provides a
623 validation of the atomistic force-field developed by Bhargava and
624 Balasubramanian (J. Chem. Phys. 2007, 127, 114510) for dynamic
625 properties.},
626 Address = {1155 16TH ST, NW, WASHINGTON, DC 20036 USA},
627 Affiliation = {Wei, Z (Reprint Author), Tech Univ Darmstadt, Petersenstr 30, D-64287 Darmstadt, Germany. {[}Wei Zhao; Leroy, Frederic; Mueller-Plathe, Florian] Tech Univ Darmstadt, D-64287 Darmstadt, Germany. {[}Balasubramanian, Sundaram] Indian Inst Sci, Jawaharlal Nehru Ctr Adv Sci Res, Chem \& Phys Mat Unit, Bangalore 560064, Karnataka, India.},
628 Author = {Wei Zhao and Leroy, Frederic and Balasubramanian, Sundaram and M\"{u}ller-Plathe, Florian},
629 Author-Email = {w.zhao@theo.chemie.tu-darmstadt.de},
630 Date-Added = {2010-04-14 11:53:37 -0400},
631 Date-Modified = {2010-04-14 11:54:20 -0400},
632 Doc-Delivery-Number = {321VS},
633 Doi = {10.1021/jp8017869},
634 Issn = {1520-6106},
635 Journal = {J. Phys. Chem. B},
636 Journal-Iso = {J. Phys. Chem. B},
637 Keywords-Plus = {TRANSPORT-PROPERTIES; FORCE-FIELD; TEMPERATURE; SIMULATION; IMIDAZOLIUM; FLUIDS; MODEL; BIS(TRIFLUOROMETHANESULFONYL)IMIDE; PYRIDINIUM; CHLORIDE},
638 Language = {English},
639 Month = {JUL 10},
640 Number = {27},
641 Number-Of-Cited-References = {49},
642 Pages = {8129-8133},
643 Publisher = {AMER CHEMICAL SOC},
644 Subject-Category = {Chemistry, Physical},
645 Times-Cited = {2},
646 Title = {Shear viscosity of the ionic liquid 1-n-butyl 3-methylimidazolium hexafluorophosphate {[}bmim]{[}PF6] computed by reverse nonequilibrium molecular dynamics},
647 Type = {Article},
648 Unique-Id = {ISI:000257335200022},
649 Volume = {112},
650 Year = {2008},
651 Bdsk-Url-1 = {http://dx.doi.org/10.1021/jp8017869%7D}}
652
653 @article{Muller-Plathe:2002,
654 Abstract = {The reverse nonequilibrium molecular dynamics {[}F. Muller-Plathe,
655 Phys. Rev. E 49, 359 (1999)] presented for the calculation of the shear
656 viscosity of Lennard-Jones liquids has been extended to atomistic
657 models of molecular liquids. The method is improved to overcome the
658 problems due to the detailed molecular models. The new technique is
659 besides a test with a Lennard-Jones fluid, applied on different
660 realistic systems: liquid nitrogen, water, and hexane, in order to
661 cover a large range of interactions and systems/architectures. We show
662 that all the advantages of the method itemized previously are still
663 valid, and that it has a very good efficiency and accuracy making it
664 very competitive. (C) 2002 American Institute of Physics.},
665 Address = {CIRCULATION \& FULFILLMENT DIV, 2 HUNTINGTON QUADRANGLE, STE 1 N O 1, MELVILLE, NY 11747-4501 USA},
666 Affiliation = {Bordat, P (Reprint Author), Max Planck Inst Polymer Res, Ackermannweg 10, D-55128 Mainz, Germany. Max Planck Inst Polymer Res, D-55128 Mainz, Germany.},
667 Author = {Bordat, P and M\"{u}ller-Plathe, F},
668 Date-Added = {2010-04-14 11:34:42 -0400},
669 Date-Modified = {2010-04-14 11:35:35 -0400},
670 Doc-Delivery-Number = {521QV},
671 Doi = {10.1063/1.1436124},
672 Issn = {0021-9606},
673 Journal = {J. Chem. Phys.},
674 Journal-Iso = {J. Chem. Phys.},
675 Keywords-Plus = {TRANSPORT-PROPERTIES; PHYSICAL-PROPERTIES; LIQUID ALKANES; N-HEPTADECANE; SIMULATION; WATER; FLOW; MIXTURES; BUTANE; NITROGEN},
676 Language = {English},
677 Month = {FEB 22},
678 Number = {8},
679 Number-Of-Cited-References = {47},
680 Pages = {3362-3369},
681 Publisher = {AMER INST PHYSICS},
682 Subject-Category = {Physics, Atomic, Molecular \& Chemical},
683 Times-Cited = {33},
684 Title = {The shear viscosity of molecular fluids: A calculation by reverse nonequilibrium molecular dynamics},
685 Type = {Article},
686 Unique-Id = {ISI:000173853600023},
687 Volume = {116},
688 Year = {2002},
689 Bdsk-Url-1 = {http://dx.doi.org/10.1063/1.1436124%7D}}
690
691 @article{ISI:000207079300006,
692 Abstract = {Non-equilibrium Molecular Dynamics Simulation
693 methods have been used to study the ability of
694 Embedded Atom Method models of the metals copper and
695 gold to reproduce the equilibrium and
696 non-equilibrium behavior of metals at a stationary
697 and at a moving solid/liquid interface. The
698 equilibrium solid/vapor interface was shown to
699 display a simple termination of the bulk until the
700 temperature of the solid reaches approximate to 90\%
701 of the bulk melting point. At and above such
702 temperatures the systems exhibit a surface
703 disodering known as surface melting. Non-equilibrium
704 simulations emulating the action of a picosecond
705 laser on the metal were performed to determine the
706 regrowth velocity. For copper, the action of a 20 ps
707 laser with an absorbed energy of 2-5 mJ/cm(2)
708 produced a regrowth velocity of 83-100 m/s, in
709 reasonable agreement with the value obtained by
710 experiment (>60 m/s). For gold, similar conditions
711 produced a slower regrowth velocity of 63 m/s at an
712 absorbed energy of 5 mJ/cm(2). This is almost a
713 factor of two too low in comparison to experiment
714 (>100 m/s). The regrowth velocities of the metals
715 seems unexpectedly close to experiment considering
716 that the free-electron contribution is ignored in
717 the Embeeded Atom Method models used.},
718 Address = {4 PARK SQUARE, MILTON PARK, ABINGDON OX14 4RN, OXON, ENGLAND},
719 Affiliation = {Clancy, P (Reprint Author), Cornell Univ, Sch Chem Engn, Ithaca, NY 14853 USA. {[}Richardson, Clifton F.; Clancy, Paulette] Cornell Univ, Sch Chem Engn, Ithaca, NY 14853 USA.},
720 Author = {Richardson, Clifton F. and Clancy, Paulette},
721 Date-Added = {2010-04-07 11:24:36 -0400},
722 Date-Modified = {2010-04-07 11:24:36 -0400},
723 Doc-Delivery-Number = {V04SY},
724 Issn = {0892-7022},
725 Journal = {Mol. Simul.},
726 Journal-Iso = {Mol. Simul.},
727 Keywords = {Non-equilibrium computer simulation; molecular dynamics; crystal growth; Embedded Atom Method models of metals},
728 Language = {English},
729 Number = {5-6},
730 Number-Of-Cited-References = {36},
731 Pages = {335-355},
732 Publisher = {TAYLOR \& FRANCIS LTD},
733 Subject-Category = {Chemistry, Physical; Physics, Atomic, Molecular \& Chemical},
734 Times-Cited = {7},
735 Title = {PICOSECOND LASER PROCESSING OF COPPER AND GOLD: A COMPUTER SIMULATION STUDY},
736 Type = {Article},
737 Unique-Id = {ISI:000207079300006},
738 Volume = {7},
739 Year = {1991}}
740
741 @article{ISI:000167766600035,
742 Abstract = {Molecular dynamics simulations are used to
743 investigate the separation of water films adjacent
744 to a hot metal surface. The simulations clearly show
745 that the water layers nearest the surface overheat
746 and undergo explosive boiling. For thick films, the
747 expansion of the vaporized molecules near the
748 surface forces the outer water layers to move away
749 from the surface. These results are of interest for
750 mass spectrometry of biological molecules, steam
751 cleaning of surfaces, and medical procedures.},
752 Address = {1155 16TH ST, NW, WASHINGTON, DC 20036 USA},
753 Affiliation = {Garrison, BJ (Reprint Author), Penn State Univ, Dept Chem, University Pk, PA 16802 USA. Penn State Univ, Dept Chem, University Pk, PA 16802 USA. Penn State Univ, Inst Mat Res, University Pk, PA 16802 USA. Univ Virginia, Dept Mat Sci \& Engn, Charlottesville, VA 22903 USA.},
754 Author = {Dou, YS and Zhigilei, LV and Winograd, N and Garrison, BJ},
755 Date-Added = {2010-03-11 15:32:14 -0500},
756 Date-Modified = {2010-03-11 15:32:14 -0500},
757 Doc-Delivery-Number = {416ED},
758 Issn = {1089-5639},
759 Journal = {J. Phys. Chem. A},
760 Journal-Iso = {J. Phys. Chem. A},
761 Keywords-Plus = {MOLECULAR-DYNAMICS SIMULATIONS; ASSISTED LASER-DESORPTION; FROZEN AQUEOUS-SOLUTIONS; COMPUTER-SIMULATION; ORGANIC-SOLIDS; VELOCITY DISTRIBUTIONS; PARTICLE BOMBARDMENT; MASS-SPECTROMETRY; PHASE EXPLOSION; LIQUID WATER},
762 Language = {English},
763 Month = {MAR 29},
764 Number = {12},
765 Number-Of-Cited-References = {65},
766 Pages = {2748-2755},
767 Publisher = {AMER CHEMICAL SOC},
768 Subject-Category = {Chemistry, Physical; Physics, Atomic, Molecular \& Chemical},
769 Times-Cited = {66},
770 Title = {Explosive boiling of water films adjacent to heated surfaces: A microscopic description},
771 Type = {Article},
772 Unique-Id = {ISI:000167766600035},
773 Volume = {105},
774 Year = {2001}}
775
776 @article{Maginn:2010,
777 Abstract = {The reverse nonequilibrium molecular dynamics
778 (RNEMD) method calculates the shear viscosity of a
779 fluid by imposing a nonphysical exchange of momentum
780 and measuring the resulting shear velocity
781 gradient. In this study we investigate the range of
782 momentum flux values over which RNEMD yields usable
783 (linear) velocity gradients. We find that nonlinear
784 velocity profiles result primarily from gradients in
785 fluid temperature and density. The temperature
786 gradient results from conversion of heat into bulk
787 kinetic energy, which is transformed back into heat
788 elsewhere via viscous heating. An expression is
789 derived to predict the temperature profile resulting
790 from a specified momentum flux for a given fluid and
791 simulation cell. Although primarily bounded above,
792 we also describe milder low-flux limitations. RNEMD
793 results for a Lennard-Jones fluid agree with
794 equilibrium molecular dynamics and conventional
795 nonequilibrium molecular dynamics calculations at
796 low shear, but RNEMD underpredicts viscosity
797 relative to conventional NEMD at high shear.},
798 Address = {CIRCULATION \& FULFILLMENT DIV, 2 HUNTINGTON QUADRANGLE, STE 1 N O 1, MELVILLE, NY 11747-4501 USA},
799 Affiliation = {Tenney, CM (Reprint Author), Univ Notre Dame, Dept Chem \& Biomol Engn, 182 Fitzpatrick Hall, Notre Dame, IN 46556 USA. {[}Tenney, Craig M.; Maginn, Edward J.] Univ Notre Dame, Dept Chem \& Biomol Engn, Notre Dame, IN 46556 USA.},
800 Article-Number = {014103},
801 Author = {Tenney, Craig M. and Maginn, Edward J.},
802 Author-Email = {ed@nd.edu},
803 Date-Added = {2010-03-09 13:08:41 -0500},
804 Date-Modified = {2010-07-19 16:21:35 -0400},
805 Doc-Delivery-Number = {542DQ},
806 Doi = {10.1063/1.3276454},
807 Funding-Acknowledgement = {U.S. Department of Energy {[}DE-FG36-08G088020]},
808 Funding-Text = {Support for this work was provided by the U.S. Department of Energy (Grant No. DE-FG36-08G088020)},
809 Issn = {0021-9606},
810 Journal = {J. Chem. Phys.},
811 Journal-Iso = {J. Chem. Phys.},
812 Keywords = {Lennard-Jones potential; molecular dynamics method; Navier-Stokes equations; viscosity},
813 Keywords-Plus = {CURRENT AUTOCORRELATION-FUNCTION; IONIC LIQUID; SIMULATIONS; TEMPERATURE},
814 Language = {English},
815 Month = {JAN 7},
816 Number = {1},
817 Number-Of-Cited-References = {20},
818 Pages = {014103},
819 Publisher = {AMER INST PHYSICS},
820 Subject-Category = {Physics, Atomic, Molecular \& Chemical},
821 Times-Cited = {0},
822 Title = {Limitations and recommendations for the calculation of shear viscosity using reverse nonequilibrium molecular dynamics},
823 Type = {Article},
824 Unique-Id = {ISI:000273472300004},
825 Volume = {132},
826 Year = {2010},
827 Bdsk-Url-1 = {http://dx.doi.org/10.1063/1.3276454}}
828
829 @article{Clancy:1992,
830 Abstract = {The regrowth velocity of a crystal from a melt
831 depends on contributions from the thermal
832 conductivity, heat gradient, and latent heat. The
833 relative contributions of these terms to the
834 regrowth velocity of the pure metals copper and gold
835 during liquid-phase epitaxy are evaluated. These
836 results are used to explain how results from
837 previous nonequilibrium molecular-dynamics
838 simulations using classical potentials are able to
839 predict regrowth velocities that are close to the
840 experimental values. Results from equilibrium
841 molecular dynamics showing the nature of the
842 solid-vapor interface of an
843 embedded-atom-method-modeled Cu57Ni43 alloy at a
844 temperature corresponding to 62\% of the melting
845 point are presented. The regrowth of this alloy
846 following a simulation of a laser-processing
847 experiment is also given, with use of nonequilibrium
848 molecular-dynamics techniques. The thermal
849 conductivity and temperature gradient in the
850 simulation of the alloy are compared to those for
851 the pure metals.},
852 Address = {ONE PHYSICS ELLIPSE, COLLEGE PK, MD 20740-3844 USA},
853 Affiliation = {CORNELL UNIV,SCH CHEM ENGN,ITHACA,NY 14853.},
854 Author = {Richardson, C.~F. and Clancy, P},
855 Date-Added = {2010-01-12 16:17:33 -0500},
856 Date-Modified = {2010-04-08 17:18:25 -0400},
857 Doc-Delivery-Number = {HX378},
858 Issn = {0163-1829},
859 Journal = {Phys. Rev. B},
860 Journal-Iso = {Phys. Rev. B},
861 Keywords-Plus = {SURFACE SEGREGATION; MOLECULAR-DYNAMICS; TRANSITION-METALS; SOLIDIFICATION; GROWTH; CU; NI},
862 Language = {English},
863 Month = {JUN 1},
864 Number = {21},
865 Number-Of-Cited-References = {24},
866 Pages = {12260-12268},
867 Publisher = {AMERICAN PHYSICAL SOC},
868 Subject-Category = {Physics, Condensed Matter},
869 Times-Cited = {11},
870 Title = {CONTRIBUTION OF THERMAL-CONDUCTIVITY TO THE CRYSTAL-REGROWTH VELOCITY OF EMBEDDED-ATOM-METHOD-MODELED METALS AND METAL-ALLOYS},
871 Type = {Article},
872 Unique-Id = {ISI:A1992HX37800010},
873 Volume = {45},
874 Year = {1992}}
875
876 @article{Bedrov:2000,
877 Abstract = {We have applied a new nonequilibrium molecular
878 dynamics (NEMD) method {[}F. Muller-Plathe,
879 J. Chem. Phys. 106, 6082 (1997)] previously applied
880 to monatomic Lennard-Jones fluids in the
881 determination of the thermal conductivity of
882 molecular fluids. The method was modified in order
883 to be applicable to systems with holonomic
884 constraints. Because the method involves imposing a
885 known heat flux it is particularly attractive for
886 systems involving long-range and many-body
887 interactions where calculation of the microscopic
888 heat flux is difficult. The predicted thermal
889 conductivities of liquid n-butane and water using
890 the imposed-flux NEMD method were found to be in a
891 good agreement with previous simulations and
892 experiment. (C) 2000 American Institute of
893 Physics. {[}S0021-9606(00)50841-1].},
894 Address = {2 HUNTINGTON QUADRANGLE, STE 1NO1, MELVILLE, NY 11747-4501 USA},
895 Affiliation = {Bedrov, D (Reprint Author), Univ Utah, Dept Chem \& Fuels Engn, 122 S Cent Campus Dr,Rm 304, Salt Lake City, UT 84112 USA. Univ Utah, Dept Chem \& Fuels Engn, Salt Lake City, UT 84112 USA. Univ Utah, Dept Mat Sci \& Engn, Salt Lake City, UT 84112 USA.},
896 Author = {Bedrov, D and Smith, GD},
897 Date-Added = {2009-11-05 18:21:18 -0500},
898 Date-Modified = {2010-04-14 11:50:48 -0400},
899 Doc-Delivery-Number = {369BF},
900 Issn = {0021-9606},
901 Journal = {J. Chem. Phys.},
902 Journal-Iso = {J. Chem. Phys.},
903 Keywords-Plus = {EFFECTIVE PAIR POTENTIALS; TRANSPORT-PROPERTIES; CANONICAL ENSEMBLE; NORMAL-BUTANE; ALGORITHMS; SHAKE; WATER},
904 Language = {English},
905 Month = {NOV 8},
906 Number = {18},
907 Number-Of-Cited-References = {26},
908 Pages = {8080-8084},
909 Publisher = {AMER INST PHYSICS},
910 Subject-Category = {Physics, Atomic, Molecular \& Chemical},
911 Times-Cited = {23},
912 Title = {Thermal conductivity of molecular fluids from molecular dynamics simulations: Application of a new imposed-flux method},
913 Type = {Article},
914 Unique-Id = {ISI:000090151400044},
915 Volume = {113},
916 Year = {2000}}
917
918 @article{ISI:000231042800044,
919 Abstract = {The reverse nonequilibrium molecular dynamics
920 method for thermal conductivities is adapted to the
921 investigation of molecular fluids. The method
922 generates a heat flux through the system by suitably
923 exchanging velocities of particles located in
924 different regions. From the resulting temperature
925 gradient, the thermal conductivity is then
926 calculated. Different variants of the algorithm and
927 their combinations with other system parameters are
928 tested: exchange of atomic velocities versus
929 exchange of molecular center-of-mass velocities,
930 different exchange frequencies, molecular models
931 with bond constraints versus models with flexible
932 bonds, united-atom versus all-atom models, and
933 presence versus absence of a thermostat. To help
934 establish the range of applicability, the algorithm
935 is tested on different models of benzene,
936 cyclohexane, water, and n-hexane. We find that the
937 algorithm is robust and that the calculated thermal
938 conductivities are insensitive to variations in its
939 control parameters. The force field, in contrast,
940 has a major influence on the value of the thermal
941 conductivity. While calculated and experimental
942 thermal conductivities fall into the same order of
943 magnitude, in most cases the calculated values are
944 systematically larger. United-atom force fields seem
945 to do better than all-atom force fields, possibly
946 because they remove high-frequency degrees of
947 freedom from the simulation, which, in nature, are
948 quantum-mechanical oscillators in their ground state
949 and do not contribute to heat conduction.},
950 Address = {1155 16TH ST, NW, WASHINGTON, DC 20036 USA},
951 Affiliation = {Zhang, MM (Reprint Author), Int Univ Bremen, POB 750 561, D-28725 Bremen, Germany. Int Univ Bremen, D-28725 Bremen, Germany. Banco Cent Brasil, Desup, Diesp, BR-01310922 Sao Paulo, Brazil.},
952 Author = {Zhang, MM and Lussetti, E and de Souza, LES and M\"{u}ller-Plathe, F},
953 Date-Added = {2009-11-05 18:17:33 -0500},
954 Date-Modified = {2009-11-05 18:17:33 -0500},
955 Doc-Delivery-Number = {952YQ},
956 Doi = {10.1021/jp0512255},
957 Issn = {1520-6106},
958 Journal = {J. Phys. Chem. B},
959 Journal-Iso = {J. Phys. Chem. B},
960 Keywords-Plus = {LENNARD-JONES LIQUIDS; TRANSPORT-COEFFICIENTS; SWOLLEN POLYMERS; SHEAR VISCOSITY; MODEL SYSTEMS; SIMULATION; BENZENE; FLUIDS; POTENTIALS; DIFFUSION},
961 Language = {English},
962 Month = {AUG 11},
963 Number = {31},
964 Number-Of-Cited-References = {42},
965 Pages = {15060-15067},
966 Publisher = {AMER CHEMICAL SOC},
967 Subject-Category = {Chemistry, Physical},
968 Times-Cited = {17},
969 Title = {Thermal conductivities of molecular liquids by reverse nonequilibrium molecular dynamics},
970 Type = {Article},
971 Unique-Id = {ISI:000231042800044},
972 Volume = {109},
973 Year = {2005},
974 Bdsk-Url-1 = {http://dx.doi.org/10.1021/jp0512255%7D}}
975
976 @article{ISI:A1997YC32200056,
977 Abstract = {Equilibrium molecular dynamics simulations have
978 been carried out in the microcanonical ensemble at
979 300 and 255 K on the extended simple point charge
980 (SPC/E) model of water {[}Berendsen et al.,
981 J. Phys. Chem. 91, 6269 (1987)]. In addition to a
982 number of static and dynamic properties, thermal
983 conductivity lambda has been calculated via
984 Green-Kubo integration of the heat current time
985 correlation functions (CF's) in the atomic and
986 molecular formalism, at wave number k=0. The
987 calculated values (0.67 +/- 0.04 W/mK at 300 K and
988 0.52 +/- 0.03 W/mK at 255 K) are in good agreement
989 with the experimental data (0.61 W/mK at 300 K and
990 0.49 W/mK at 255 K). A negative long-time tail of
991 the heat current CF, more apparent at 255 K, is
992 responsible for the anomalous decrease of lambda
993 with temperature. An analysis of the dynamical modes
994 contributing to lambda has shown that its value is
995 due to two low-frequency exponential-like modes, a
996 faster collisional mode, with positive contribution,
997 and a slower one, which determines the negative
998 long-time tail. A comparison of the molecular and
999 atomic spectra of the heat current CF has suggested
1000 that higher-frequency modes should not contribute to
1001 lambda in this temperature range. Generalized
1002 thermal diffusivity D-T(k) decreases as a function
1003 of k, after an initial minor increase at k =
1004 k(min). The k dependence of the generalized
1005 thermodynamic properties has been calculated in the
1006 atomic and molecular formalisms. The observed
1007 differences have been traced back to intramolecular
1008 or intermolecular rotational effects and related to
1009 the partial structure functions. Finally, from the
1010 results we calculated it appears that the SPC/E
1011 model gives results in better agreement with
1012 experimental data than the transferable
1013 intermolecular potential with four points TIP4P
1014 water model {[}Jorgensen et al., J. Chem. Phys. 79,
1015 926 (1983)], with a larger improvement for, e.g.,
1016 diffusion, viscosities, and dielectric properties
1017 and a smaller one for thermal conductivity. The
1018 SPC/E model shares, to a smaller extent, the
1019 insufficient slowing down of dynamics at low
1020 temperature already found for the TIP4P water
1021 model.},
1022 Address = {ONE PHYSICS ELLIPSE, COLLEGE PK, MD 20740-3844 USA},
1023 Affiliation = {UNIV PISA,DIPARTIMENTO CHIM \& CHIM IND,I-56126 PISA,ITALY. CNR,IST FIS ATOM \& MOL,I-56127 PISA,ITALY.},
1024 Author = {Bertolini, D and Tani, A},
1025 Date-Added = {2009-10-30 15:41:21 -0400},
1026 Date-Modified = {2009-10-30 15:41:21 -0400},
1027 Doc-Delivery-Number = {YC322},
1028 Issn = {1063-651X},
1029 Journal = {Phys. Rev. E},
1030 Journal-Iso = {Phys. Rev. E},
1031 Keywords-Plus = {TIME-CORRELATION-FUNCTIONS; LENNARD-JONES LIQUID; TRANSPORT-PROPERTIES; SUPERCOOLED WATER; DENSITY; SIMULATIONS; RELAXATION; VELOCITY; ELECTRON; FLUIDS},
1032 Language = {English},
1033 Month = {OCT},
1034 Number = {4},
1035 Number-Of-Cited-References = {35},
1036 Pages = {4135-4151},
1037 Publisher = {AMERICAN PHYSICAL SOC},
1038 Subject-Category = {Physics, Fluids \& Plasmas; Physics, Mathematical},
1039 Times-Cited = {18},
1040 Title = {Thermal conductivity of water: Molecular dynamics and generalized hydrodynamics results},
1041 Type = {Article},
1042 Unique-Id = {ISI:A1997YC32200056},
1043 Volume = {56},
1044 Year = {1997}}
1045
1046 @article{Meineke:2005gd,
1047 Abstract = {OOPSE is a new molecular dynamics simulation program
1048 that is capable of efficiently integrating equations
1049 of motion for atom types with orientational degrees
1050 of freedom (e.g. #sticky# atoms and point
1051 dipoles). Transition metals can also be simulated
1052 using the embedded atom method (EAM) potential
1053 included in the code. Parallel simulations are
1054 carried out using the force-based decomposition
1055 method. Simulations are specified using a very
1056 simple C-based meta-data language. A number of
1057 advanced integrators are included, and the basic
1058 integrator for orientational dynamics provides
1059 substantial improvements over older quaternion-based
1060 schemes.},
1061 Address = {111 RIVER ST, HOBOKEN, NJ 07030 USA},
1062 Author = {Meineke, M. A. and Vardeman, C. F. and Lin, T and Fennell, CJ and Gezelter, J. D.},
1063 Date-Added = {2009-10-01 18:43:03 -0400},
1064 Date-Modified = {2010-04-13 09:11:16 -0400},
1065 Doi = {DOI 10.1002/jcc.20161},
1066 Isi = {000226558200006},
1067 Isi-Recid = {142688207},
1068 Isi-Ref-Recids = {67885400 50663994 64190493 93668415 46699855 89992422 57614458 49016001 61447131 111114169 68770425 52728075 102422498 66381878 32391149 134477335 53221357 9929643 59492217 69681001 99223832 142688208 94600872 91658572 54857943 117365867 69323123 49588888 109970172 101670714 142688209 121603296 94652379 96449138 99938010 112825758 114905670 86802042 121339042 104794914 82674909 72096791 93668384 90513335 142688210 23060767 63731466 109033408 76303716 31384453 97861662 71842426 130707771 125809946 66381889 99676497},
1069 Journal = {J. Comp. Chem.},
1070 Keywords = {OOPSE; molecular dynamics},
1071 Month = feb,
1072 Number = {3},
1073 Pages = {252-271},
1074 Publisher = {JOHN WILEY \& SONS INC},
1075 Times-Cited = {9},
1076 Title = {OOPSE: An object-oriented parallel simulation engine for molecular dynamics},
1077 Volume = {26},
1078 Year = {2005},
1079 Bdsk-Url-1 = {http://gateway.isiknowledge.com/gateway/Gateway.cgi?GWVersion=2&SrcAuth=Alerting&SrcApp=Alerting&DestApp=WOS&DestLinkType=FullRecord;KeyUT=000226558200006},
1080 Bdsk-Url-2 = {http://dx.doi.org/10.1002/jcc.20161}}
1081
1082 @article{ISI:000080382700030,
1083 Abstract = {A nonequilibrium method for calculating the shear
1084 viscosity is presented. It reverses the
1085 cause-and-effect picture customarily used in
1086 nonequilibrium molecular dynamics: the effect, the
1087 momentum flux or stress, is imposed, whereas the
1088 cause, the velocity gradient or shear rate, is
1089 obtained from the simulation. It differs from other
1090 Norton-ensemble methods by the way in which the
1091 steady-state momentum flux is maintained. This
1092 method involves a simple exchange of particle
1093 momenta, which is easy to implement. Moreover, it
1094 can be made to conserve the total energy as well as
1095 the total linear momentum, so no coupling to an
1096 external temperature bath is needed. The resulting
1097 raw data, the velocity profile, is a robust and
1098 rapidly converging property. The method is tested on
1099 the Lennard-Jones fluid near its triple point. It
1100 yields a viscosity of 3.2-3.3, in Lennard-Jones
1101 reduced units, in agreement with literature
1102 results. {[}S1063-651X(99)03105-0].},
1103 Address = {ONE PHYSICS ELLIPSE, COLLEGE PK, MD 20740-3844 USA},
1104 Affiliation = {Muller-Plathe, F (Reprint Author), Max Planck Inst Polymerforsch, Ackermannweg 10, D-55128 Mainz, Germany. Max Planck Inst Polymerforsch, D-55128 Mainz, Germany.},
1105 Author = {M\"{u}ller-Plathe, F},
1106 Date-Added = {2009-10-01 14:07:30 -0400},
1107 Date-Modified = {2009-10-01 14:07:30 -0400},
1108 Doc-Delivery-Number = {197TX},
1109 Issn = {1063-651X},
1110 Journal = {Phys. Rev. E},
1111 Journal-Iso = {Phys. Rev. E},
1112 Language = {English},
1113 Month = {MAY},
1114 Number = {5, Part A},
1115 Number-Of-Cited-References = {17},
1116 Pages = {4894-4898},
1117 Publisher = {AMERICAN PHYSICAL SOC},
1118 Subject-Category = {Physics, Fluids \& Plasmas; Physics, Mathematical},
1119 Times-Cited = {57},
1120 Title = {Reversing the perturbation in nonequilibrium molecular dynamics: An easy way to calculate the shear viscosity of fluids},
1121 Type = {Article},
1122 Unique-Id = {ISI:000080382700030},
1123 Volume = {59},
1124 Year = {1999}}
1125
1126 @article{Maginn:2007,
1127 Abstract = {Atomistic simulations are conducted to examine the
1128 dependence of the viscosity of
1129 1-ethyl-3-methylimidazolium
1130 bis(trifluoromethanesulfonyl)imide on temperature
1131 and water content. A nonequilibrium molecular
1132 dynamics procedure is utilized along with an
1133 established fixed charge force field. It is found
1134 that the simulations quantitatively capture the
1135 temperature dependence of the viscosity as well as
1136 the drop in viscosity that occurs with increasing
1137 water content. Using mixture viscosity models, we
1138 show that the relative drop in viscosity with water
1139 content is actually less than that that would be
1140 predicted for an ideal system. This finding is at
1141 odds with the popular notion that small amounts of
1142 water cause an unusually large drop in the viscosity
1143 of ionic liquids. The simulations suggest that, due
1144 to preferential association of water with anions and
1145 the formation of water clusters, the excess molar
1146 volume is negative. This means that dissolved water
1147 is actually less effective at lowering the viscosity
1148 of these mixtures when compared to a solute obeying
1149 ideal mixing behavior. The use of a nonequilibrium
1150 simulation technique enables diffusive behavior to
1151 be observed on the time scale of the simulations,
1152 and standard equilibrium molecular dynamics resulted
1153 in sub-diffusive behavior even over 2 ns of
1154 simulation time.},
1155 Address = {1155 16TH ST, NW, WASHINGTON, DC 20036 USA},
1156 Affiliation = {Maginn, EJ (Reprint Author), Univ Notre Dame, Dept Chem \& Biomol Engn, 182 Fitzpatrick Hall, Notre Dame, IN 46556 USA. Univ Notre Dame, Dept Chem \& Biomol Engn, Notre Dame, IN 46556 USA.},
1157 Author = {Kelkar, Manish S. and Maginn, Edward J.},
1158 Author-Email = {ed@nd.edu},
1159 Date-Added = {2009-09-29 17:07:17 -0400},
1160 Date-Modified = {2010-04-14 12:51:02 -0400},
1161 Doc-Delivery-Number = {163VA},
1162 Doi = {10.1021/jp0686893},
1163 Issn = {1520-6106},
1164 Journal = {J. Phys. Chem. B},
1165 Journal-Iso = {J. Phys. Chem. B},
1166 Keywords-Plus = {MOLECULAR-DYNAMICS SIMULATION; MOMENTUM IMPULSE RELAXATION; FORCE-FIELD; TRANSPORT-PROPERTIES; PHYSICAL-PROPERTIES; SIMPLE FLUID; CHLORIDE; MODEL; SALTS; ARCHITECTURE},
1167 Language = {English},
1168 Month = {MAY 10},
1169 Number = {18},
1170 Number-Of-Cited-References = {57},
1171 Pages = {4867-4876},
1172 Publisher = {AMER CHEMICAL SOC},
1173 Subject-Category = {Chemistry, Physical},
1174 Times-Cited = {35},
1175 Title = {Effect of temperature and water content on the shear viscosity of the ionic liquid 1-ethyl-3-methylimidazolium bis(trifluoromethanesulfonyl)imide as studied by atomistic simulations},
1176 Type = {Article},
1177 Unique-Id = {ISI:000246190100032},
1178 Volume = {111},
1179 Year = {2007},
1180 Bdsk-Url-1 = {http://dx.doi.org/10.1021/jp0686893%7D},
1181 Bdsk-Url-2 = {http://dx.doi.org/10.1021/jp0686893}}
1182
1183 @article{MullerPlathe:1997xw,
1184 Abstract = {A nonequilibrium molecular dynamics method for
1185 calculating the thermal conductivity is
1186 presented. It reverses the usual cause and effect
1187 picture. The ''effect,'' the heat flux, is imposed
1188 on the system and the ''cause,'' the temperature
1189 gradient is obtained from the simulation. Besides
1190 being very simple to implement, the scheme offers
1191 several advantages such as compatibility with
1192 periodic boundary conditions, conservation of total
1193 energy and total linear momentum, and the sampling
1194 of a rapidly converging quantity (temperature
1195 gradient) rather than a slowly converging one (heat
1196 flux). The scheme is tested on the Lennard-Jones
1197 fluid. (C) 1997 American Institute of Physics.},
1198 Address = {WOODBURY},
1199 Author = {M\"{u}ller-Plathe, F.},
1200 Cited-Reference-Count = {13},
1201 Date = {APR 8},
1202 Date-Added = {2009-09-21 16:51:21 -0400},
1203 Date-Modified = {2009-09-21 16:51:21 -0400},
1204 Document-Type = {Article},
1205 Isi = {ISI:A1997WR62000032},
1206 Isi-Document-Delivery-Number = {WR620},
1207 Iso-Source-Abbreviation = {J. Chem. Phys.},
1208 Issn = {0021-9606},
1209 Journal = {J. Chem. Phys.},
1210 Language = {English},
1211 Month = {Apr},
1212 Number = {14},
1213 Page-Count = {4},
1214 Pages = {6082--6085},
1215 Publication-Type = {J},
1216 Publisher = {AMER INST PHYSICS},
1217 Publisher-Address = {CIRCULATION FULFILLMENT DIV, 500 SUNNYSIDE BLVD, WOODBURY, NY 11797-2999},
1218 Reprint-Address = {MullerPlathe, F, MAX PLANCK INST POLYMER RES, D-55128 MAINZ, GERMANY.},
1219 Source = {J CHEM PHYS},
1220 Subject-Category = {Physics, Atomic, Molecular & Chemical},
1221 Times-Cited = {106},
1222 Title = {A simple nonequilibrium molecular dynamics method for calculating the thermal conductivity},
1223 Volume = {106},
1224 Year = {1997}}
1225
1226 @article{Muller-Plathe:1999ek,
1227 Abstract = {A novel non-equilibrium method for calculating
1228 transport coefficients is presented. It reverses the
1229 experimental cause-and-effect picture, e.g. for the
1230 calculation of viscosities: the effect, the momentum
1231 flux or stress, is imposed, whereas the cause, the
1232 velocity gradient or shear rates, is obtained from
1233 the simulation. It differs from other
1234 Norton-ensemble methods by the way, in which the
1235 steady-state fluxes are maintained. This method
1236 involves a simple exchange of particle momenta,
1237 which is easy to implement and to analyse. Moreover,
1238 it can be made to conserve the total energy as well
1239 as the total linear momentum, so no thermostatting
1240 is needed. The resulting raw data are robust and
1241 rapidly converging. The method is tested on the
1242 calculation of the shear viscosity, the thermal
1243 conductivity and the Soret coefficient (thermal
1244 diffusion) for the Lennard-Jones (LJ) fluid near its
1245 triple point. Possible applications to other
1246 transport coefficients and more complicated systems
1247 are discussed. (C) 1999 Elsevier Science Ltd. All
1248 rights reserved.},
1249 Address = {THE BOULEVARD, LANGFORD LANE, KIDLINGTON, OXFORD OX5 1GB, OXON, ENGLAND},
1250 Author = {M\"{u}ller-Plathe, F and Reith, D},
1251 Date-Added = {2009-09-21 16:47:07 -0400},
1252 Date-Modified = {2009-09-21 16:47:07 -0400},
1253 Isi = {000082266500004},
1254 Isi-Recid = {111564960},
1255 Isi-Ref-Recids = {64516210 89773595 53816621 60134000 94875498 60964023 90228608 85968509 86405859 63979644 108048497 87560156 577165 103281654 111564961 83735333 99953572 88476740 110174781 111564963 6599000 75892253},
1256 Journal = {Computational and Theoretical Polymer Science},
1257 Keywords = {viscosity; Ludwig-Soret effect; thermal conductivity; Onsager coefficents; non-equilibrium molecular dynamics},
1258 Number = {3-4},
1259 Pages = {203-209},
1260 Publisher = {ELSEVIER SCI LTD},
1261 Times-Cited = {15},
1262 Title = {Cause and effect reversed in non-equilibrium molecular dynamics: an easy route to transport coefficients},
1263 Volume = {9},
1264 Year = {1999},
1265 Bdsk-Url-1 = {http://gateway.isiknowledge.com/gateway/Gateway.cgi?GWVersion=2&SrcAuth=Alerting&SrcApp=Alerting&DestApp=WOS&DestLinkType=FullRecord;KeyUT=000082266500004}}
1266
1267 @article{Viscardy:2007lq,
1268 Abstract = {The thermal conductivity is calculated with the
1269 Helfand-moment method in the Lennard-Jones fluid
1270 near the triple point. The Helfand moment of thermal
1271 conductivity is here derived for molecular dynamics
1272 with periodic boundary conditions. Thermal
1273 conductivity is given by a generalized Einstein
1274 relation with this Helfand moment. The authors
1275 compute thermal conductivity by this new method and
1276 compare it with their own values obtained by the
1277 standard Green-Kubo method. The agreement is
1278 excellent. (C) 2007 American Institute of Physics.},
1279 Address = {CIRCULATION \& FULFILLMENT DIV, 2 HUNTINGTON QUADRANGLE, STE 1 N O 1, MELVILLE, NY 11747-4501 USA},
1280 Author = {Viscardy, S. and Servantie, J. and Gaspard, P.},
1281 Date-Added = {2009-09-21 16:37:20 -0400},
1282 Date-Modified = {2010-07-19 16:18:44 -0400},
1283 Doi = {DOI 10.1063/1.2724821},
1284 Isi = {000246453900035},
1285 Isi-Recid = {156192451},
1286 Isi-Ref-Recids = {18794442 84473620 156192452 41891249 90040203 110174972 59859940 47256160 105716249 91804339 93329429 95967319 6199670 1785176 105872066 6325196 65361295 71941152 4307928 23120502 54053395 149068110 4811016 99953572 59859908 132156782 156192449},
1287 Journal = {J. Chem. Phys.},
1288 Month = may,
1289 Number = {18},
1290 Pages = {184513},
1291 Publisher = {AMER INST PHYSICS},
1292 Times-Cited = {3},
1293 Title = {Transport and Helfand moments in the Lennard-Jones fluid. II. Thermal conductivity},
1294 Volume = {126},
1295 Year = {2007},
1296 Bdsk-Url-1 = {http://gateway.isiknowledge.com/gateway/Gateway.cgi?GWVersion=2&SrcAuth=Alerting&SrcApp=Alerting&DestApp=WOS&DestLinkType=FullRecord;KeyUT=000246453900035},
1297 Bdsk-Url-2 = {http://dx.doi.org/10.1063/1.2724821}}
1298
1299 @article{Viscardy:2007bh,
1300 Abstract = {The authors propose a new method, the Helfand-moment
1301 method, to compute the shear viscosity by
1302 equilibrium molecular dynamics in periodic
1303 systems. In this method, the shear viscosity is
1304 written as an Einstein-type relation in terms of the
1305 variance of the so-called Helfand moment. This
1306 quantity is modified in order to satisfy systems
1307 with periodic boundary conditions usually considered
1308 in molecular dynamics. They calculate the shear
1309 viscosity in the Lennard-Jones fluid near the triple
1310 point thanks to this new technique. They show that
1311 the results of the Helfand-moment method are in
1312 excellent agreement with the results of the standard
1313 Green-Kubo method. (C) 2007 American Institute of
1314 Physics.},
1315 Address = {CIRCULATION \& FULFILLMENT DIV, 2 HUNTINGTON QUADRANGLE, STE 1 N O 1, MELVILLE, NY 11747-4501 USA},
1316 Author = {Viscardy, S. and Servantie, J. and Gaspard, P.},
1317 Date-Added = {2009-09-21 16:37:19 -0400},
1318 Date-Modified = {2010-07-19 16:19:03 -0400},
1319 Doi = {DOI 10.1063/1.2724820},
1320 Isi = {000246453900034},
1321 Isi-Recid = {156192449},
1322 Isi-Ref-Recids = {18794442 89109900 84473620 86837966 26564374 23367140 83161139 75750220 90040203 110174972 5885 67722779 91461489 42484251 77907850 93329429 95967319 105716249 6199670 1785176 105872066 6325196 129596740 120782555 51131244 65361295 41141868 4307928 21555860 23120502 563068 120721875 142813985 135942402 4811016 86224873 57621419 85506488 89860062 44796632 51381285 132156779 156192450 132156782 156192451},
1323 Journal = {J. Chem. Phys.},
1324 Month = may,
1325 Number = {18},
1326 Pages = {184512},
1327 Publisher = {AMER INST PHYSICS},
1328 Times-Cited = {1},
1329 Title = {Transport and Helfand moments in the Lennard-Jones fluid. I. Shear viscosity},
1330 Volume = {126},
1331 Year = {2007},
1332 Bdsk-Url-1 = {http://gateway.isiknowledge.com/gateway/Gateway.cgi?GWVersion=2&SrcAuth=Alerting&SrcApp=Alerting&DestApp=WOS&DestLinkType=FullRecord;KeyUT=000246453900034},
1333 Bdsk-Url-2 = {http://dx.doi.org/10.1063/1.2724820}}
1334
1335 @inproceedings{384119,
1336 Address = {New York, NY, USA},
1337 Author = {Fortune, Steven},
1338 Booktitle = {ISSAC '01: Proceedings of the 2001 international symposium on Symbolic and algebraic computation},
1339 Doi = {http://doi.acm.org/10.1145/384101.384119},
1340 Isbn = {1-58113-417-7},
1341 Location = {London, Ontario, Canada},
1342 Pages = {121--128},
1343 Publisher = {ACM},
1344 Title = {Polynomial root finding using iterated Eigenvalue computation},
1345 Year = {2001},
1346 Bdsk-Url-1 = {http://doi.acm.org/10.1145/384101.384119}}