trunk/iceiPaper/iceiPaper.tex

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\begin{document}

\title{A Free Energy Study of Low Temperature and Anomolous Ice}

\author{Christopher J. Fennell and J. Daniel Gezelter{\thefootnote}
\footnote[1]{Corresponding author. \ Electronic mail: gezelter@nd.edu}}

\address{Department of Chemistry and Biochemistry\\ University of Notre Dame\\
Notre Dame, Indiana 46556}

\date{\today}

%\maketitle
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\begin{abstract}
\end{abstract}

\maketitle

\newpage

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%                              BODY OF TEXT
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\section{Introduction}

\section{Methods}

Canonical ensemble (NVT) molecular dynamics calculations were
performed using the OOPSE (Object-Oriented Parallel Simulation Engine)
molecular mechanics package. All molecules were treated as rigid
bodies, with orientational motion propogated using the symplectic DLM
integration method. Details about the implementation of these
techniques can be found in a recent publication.\cite{Meineke05} 

Thermodynamic integration was utilized to calculate the free energy of
several ice crystals at 200 K using the TIP3P, TIP4P, TIP5P, SPC/E,
SSD/RF, and SSD/E water models. Liquid state free energies at 300 and
400 K for all of these water models were also determined using this
same technique, in order to determine melting points and generate
phase diagrams. All simulations were carried out at densities
resulting in a pressure of approximately 1 atm at their respective
temperatures.

A single thermodynamic integration involves a sequence of simulations
over which the system of interest is converted into a reference system
for which the free energy is known. This transformation path is then
integrated in order to determine the free energy difference between
the two states:
\begin{equation}
\begin{center}
\Delta A = \int_0^1\left\langle\frac{\partial V(\lambda 
)}{\partial\lambda}\right\rangle_\lambda d\lambda,
\end{center}
\end{equation}
where $V$ is the interaction potential and $\lambda$ is the
transformation parameter. Simulations are distributed unevenly along
this path in order to sufficiently sample the regions of greatest
change in the potential. Typical integrations in this study consisted
of $\sim$25 simulations ranging from 300 ps (for the unaltered system)
to 75 ps (near the reference state) in length.

For the thermodynamic integration of molecular crystals, the Einstein
Crystal is chosen as the reference state that the system is converted
to over the course of the simulation. In an Einstein Crystal, the
molecules are harmonically restrained at their ideal lattice locations
and orientations. The partition function for a molecular crystal
restrained in this fashion has been evaluated, and the Helmholtz Free
Energy ({\it A}) is given by
\begin{eqnarray}
A = E_m\ -\ kT\ln \left (\frac{kT}{h\nu}\right )^3&-&kT\ln \left
[\pi^\frac{1}{2}\left (\frac{8\pi^2I_\mathrm{A}kT}{h^2}\right
)^\frac{1}{2}\left (\frac{8\pi^2I_\mathrm{B}kT}{h^2}\right
)^\frac{1}{2}\left (\frac{8\pi^2I_\mathrm{C}kT}{h^2}\right
)^\frac{1}{2}\right ] \nonumber \\ &-& kT\ln \left [\frac{kT}{2(\pi
K_\omega K_\theta)^{\frac{1}{2}}}\exp\left
(-\frac{kT}{2K_\theta}\right)\int_0^{\left (\frac{kT}{2K_\theta}\right
)^\frac{1}{2}}\exp(t^2)\mathrm{d}t\right ],
\label{ecFreeEnergy}
\end{eqnarray}
where $2\pi\nu = (K_\mathrm{v}/m)^{1/2}$.\cite{Baez95a} In equation
\ref{ecFreeEnergy}, $K_\mathrm{v}$, $K_\mathrm{\theta}$, and
$K_\mathrm{\omega}$ are the spring constants restraining translational
motion and deflection of and rotation around the principle axis of the
molecule respectively (Fig. \ref{waterSpring}), and $E_m$ is the
minimum potential energy of the ideal crystal. In the case of
molecular liquids, the ideal vapor is chosen as the target reference
state.
\begin{figure}
\includegraphics[scale=1.0]{rotSpring.eps}
\caption{Possible orientational motions for a restrained molecule. 
$\theta$ angles correspond to displacement from the body-frame {\it
z}-axis, while $\omega$ angles correspond to rotation about the
body-frame {\it z}-axis. $K_\theta$ and $K_\omega$ are spring
constants for the harmonic springs restraining motion in the $\theta$
and $\omega$ directions.}
\label{waterSpring}
\end{figure}

Charge, dipole, and Lennard-Jones interactions were modified by a
cubic switching between 100\% and 85\% of the cutoff value (9 \AA ). By
applying this function, these interactions are smoothly truncated,
thereby avoiding poor energy conserving dynamics resulting from
harsher truncation schemes. The effect of a long-range correction was
also investigated on select model systems in a variety of manners. For
the SSD/RF model, a reaction field with a fixed dielectric constant of
80 was applied in all simulations.\cite{Onsager36} For a series of the
least computationally expensive models (SSD/E, SSD/RF, and TIP3P),
simulations were performed with longer cutoffs of 12 and 15 \AA\ to
compare with the 9 \AA\ cutoff results. Finally, results from the use
of an Ewald summation were estimated for TIP3P and SPC/E by performing
calculations with Particle-Mesh Ewald (PME) in the TINKER molecular
mechanics software package. TINKER was chosen because it can also
propogate the motion of rigid-bodies, and provides the most direct
comparison to the results from OOPSE. The calculated energy difference
in the presence and absence of PME was applied to the previous results
in order to predict changes in the free energy landscape.

\section{Results and discussion}

The free energy of proton ordered Ice-{\it i} was calculated and
compared with the free energies of proton ordered variants of the
experimentally observed low-density ice polymorphs, $I_h$ and $I_c$,
as well as the higher density ice B, observed by B\`{a}ez and Clancy
and thought to be the minimum free energy structure for the SPC/E
model at ambient conditions (Table \ref{freeEnergy}).\cite{Baez95b}
Ice XI, the experimentally observed proton ordered variant of ice
$I_h$, was investigated initially, but it was found not to be as
stable as antiferroelectric variants of proton ordered or even proton
disordered ice$I_h$.\cite{Davidson84} The proton ordered variant of
ice $I_h$ used here is a simple antiferroelectric version that has an
8 molecule unit cell. The crystals contained 648 or 1728 molecules for
ice B, 1024 or 1280 molecules for ice $I_h$, 1000 molecules for ice
$I_c$, or 1024 molecules for Ice-{\it i}. The larger crystal sizes
were necessary for simulations involving larger cutoff values.

\begin{table*}
\begin{minipage}{\linewidth}
\renewcommand{\thefootnote}{\thempfootnote}
\begin{center}
\caption{Calculated free energies for several ice polymorphs with a 
variety of common water models. All calculations used a cutoff radius
of 9 \AA\ and were performed at 200 K and $\sim$1 atm. Units are
kcal/mol. *Ice $I_c$ is unstable at 200 K using SSD/RF.}
\begin{tabular}{ l  c  c  c  c }
\hline \\[-7mm]
\ \quad \ Water Model\ \ & \ \quad \ \ \ \ $I_h$ \ \ & \ \quad \ \ \ \ $I_c$ \ \  & \ \quad \ \ \ \ B \ \  & \ \quad \ \ \ Ice-{\it i} \ \quad \ \\
\hline \\[-3mm]
\ \quad \ TIP3P  & \ \quad \ -11.41 & \ \quad \ -11.23 & \ \quad \ -11.82 & \quad -12.30\\
\ \quad \ TIP4P  & \ \quad \ -11.84 & \ \quad \ -12.04 & \ \quad \ -12.08 & \quad -12.33\\
\ \quad \ TIP5P  & \ \quad \ -11.85 & \ \quad \ -11.86 & \ \quad \ -11.96 & \quad -12.29\\
\ \quad \ SPC/E  & \ \quad \ -12.67 & \ \quad \ -12.96 & \ \quad \ -13.25 & \quad -13.55\\
\ \quad \ SSD/E  & \ \quad \ -11.27 & \ \quad \ -11.19 & \ \quad \ -12.09 & \quad -12.54\\
\ \quad \ SSD/RF & \ \quad \ -11.51 & \ \quad \ NA* & \ \quad \ -12.08 & \quad -12.29\\
\end{tabular}
\label{freeEnergy}
\end{center}
\end{minipage}
\end{table*}

The free energy values computed for the studied polymorphs indicate
that Ice-{\it i} is the most stable state for all of the common water
models studied. With the free energy at these state points, the
temperature and pressure dependence of the free energy was used to
project to other state points and build phase diagrams. Figures
\ref{tp3phasedia} and \ref{ssdrfphasedia} are example diagrams built
from the free energy results. All other models have similar structure,
only the crossing points between these phases exist at different
temperatures and pressures. It is interesting to note that ice $I$
does not exist in either cubic or hexagonal form in any of the phase
diagrams for any of the models. For purposes of this study, ice B is
representative of the dense ice polymorphs. A recent study by Sanz
{\it et al.} goes into detail on the phase diagrams for SPC/E and
TIP4P in the high pressure regime.\cite{Sanz04} 
\begin{figure}
\includegraphics[width=\linewidth]{tp3PhaseDia.eps}
\caption{Phase diagram for the TIP3P water model in the low pressure 
regime. The displayed $T_m$ and $T_b$ values are good predictions of
the experimental values; however, the solid phases shown are not the
experimentally observed forms. Both cubic and hexagonal ice $I$ are
higher in energy and don't appear in the phase diagram.}
\label{tp3phasedia}
\end{figure}
\begin{figure}
\includegraphics[width=\linewidth]{ssdrfPhaseDia.eps}
\caption{Phase diagram for the SSD/RF water model in the low pressure 
regime. Calculations producing these results were done under an
applied reaction field. It is interesting to note that this
computationally efficient model (over 3 times more efficient than
TIP3P) exhibits phase behavior similar to the less computationally
conservative charge based models.}
\label{ssdrfphasedia}
\end{figure}

\begin{table*}
\begin{minipage}{\linewidth}
\renewcommand{\thefootnote}{\thempfootnote}
\begin{center}
\caption{Melting ($T_m$), boiling ($T_b$), and sublimation ($T_s$) 
temperatures of several common water models compared with experiment.}
\begin{tabular}{ l  c  c  c  c  c  c  c }
\hline \\[-7mm]
\ \ Equilibria Point\ \ & \ \ \ \ \ TIP3P \ \ & \ \ \ \ \ TIP4P \ \ & \ \quad \ \ \ \ TIP5P \ \ & \ \ \ \ \ SPC/E \ \ & \ \ \ \ \ SSD/E \ \ & \ \ \ \ \ SSD/RF \ \ & \ \ \ \ \ Exp. \ \ \\
\hline \\[-3mm]
\ \ $T_m$ (K)  & \ \ 269 & \ \ 265 & \ \ 271 &  297 & \ \ - & \ \ 278 & \ \ 273\\
\ \ $T_b$ (K)  & \ \ 357 & \ \ 354 & \ \ 337 &  396 & \ \ - & \ \ 349 & \ \ 373\\
\ \ $T_s$ (K)  & \ \ - & \ \ - & \ \ - &  - & \ \ 355 & \ \ - & \ \ -\\
\end{tabular}
\label{meltandboil}
\end{center}
\end{minipage}
\end{table*}

Table \ref{meltandboil} lists the melting and boiling temperatures
calculated from this work. Surprisingly, most of these models have
melting points that compare quite favorably with experiment. The
unfortunate aspect of this result is that this phase change occurs
between Ice-{\it i} and the liquid state rather than ice $I_h$ and the
liquid state. These results are actually not contrary to previous
studies in the literature. Earlier free energy studies of ice $I$
using TIP4P predict a $T_m$ ranging from 214 to 238 K (differences
being attributed to choice of interaction truncation and different
ordered and disordered molecular arrangements). If the presence of ice
B and Ice-{\it i} were omitted, a $T_m$ value around 210 K would be
predicted from this work. However, the $T_m$ from Ice-{\it i} is
calculated at 265 K, significantly higher in temperature than the
previous studies. Also of interest in these results is that SSD/E does
not exhibit a melting point at 1 atm, but it shows a sublimation point
at 355 K. This is due to the significant stability of Ice-{\it i} over
all other polymorphs for this particular model under these
conditions. While troubling, this behavior turned out to be
advantagious in that it facilitated the spontaneous crystallization of
Ice-{\it i}. These observations provide a warning that simulations of
SSD/E as a ``liquid'' near 300 K are actually metastable and run the
risk of spontaneous crystallization. However, this risk changes when
applying a longer cutoff.

\begin{figure}
\includegraphics[width=\linewidth]{cutoffChange.eps}
\caption{Free energy as a function of cutoff radius for (A) SSD/E, (B) 
TIP3P, and (C) SSD/RF. Data points omitted include SSD/E: $I_c$ 12
\AA\, TIP3P: $I_c$ 12 \AA\ and B 12 \AA\, and SSD/RF: $I_c$ 9
\AA\. These crystals are unstable at 200 K and rapidly convert into a
liquid. The connecting lines are qualitative visual aid.}
\label{incCutoff}
\end{figure}

Increasing the cutoff radius in simulations of the more
computationally efficient water models was done in order to evaluate
the trend in free energy values when moving to systems that do not
involve potential truncation. As seen in Fig. \ref{incCutoff}, the
free energy of all the ice polymorphs show a substantial dependence on
cutoff radius. In general, there is a narrowing of the free energy
differences while moving to greater cutoff radius. This trend is much
more subtle in the case of SSD/RF, indicating that the free energies
calculated with a reaction field present provide a more accurate
picture of the free energy landscape in the absence of potential
truncation. 

To further study the changes resulting to the inclusion of a
long-range interaction correction, the effect of an Ewald summation
was estimated by applying the potential energy difference do to its
inclusion in systems in the presence and absence of the
correction. This was accomplished by calculation of the potential
energy of identical crystals with and without PME using TINKER. The
free energies for the investigated polymorphs using the TIP3P and
SPC/E water models are shown in Table \ref{pmeShift}. TIP4P and TIP5P
are not fully supported in TINKER, so the results for these models
could not be estimated. The same trend pointed out through increase of
cutoff radius is observed in these results. Ice-{\it i} is the
preferred polymorph at ambient conditions for both the TIP3P and SPC/E
water models; however, there is a narrowing of the free energy
differences between the various solid forms. In the case of SPC/E this
narrowing is significant enough that it becomes less clear cut that
Ice-{\it i} is the most stable polymorph, and is possibly metastable
with respect to ice B and possibly ice $I_c$. However, these results
do not significantly alter the finding that the Ice-{\it i} polymorph
is a stable crystal structure that should be considered when studying
the phase behavior of water models.

\begin{table*}
\begin{minipage}{\linewidth}
\renewcommand{\thefootnote}{\thempfootnote}
\begin{center}
\caption{The free energy of the studied ice polymorphs after applying 
the energy difference attributed to the inclusion of the PME
long-range interaction correction. Units are kcal/mol.}
\begin{tabular}{ l  c  c  c  c }
\hline \\[-7mm]
\ \ Water Model \ \ & \ \ \ \ \ $I_h$ \ \ & \ \ \ \ \ $I_c$ \ \ & \ \quad \ \ \ \ B \ \ & \ \ \ \ \ Ice-{\it i} \ \ \\
\hline \\[-3mm]
\ \ TIP3P  & \ \ -11.53 & \ \ -11.24 & \ \ -11.51 & \ \ -11.67\\
\ \ SPC/E  & \ \ -12.77 & \ \ -12.92 & \ \ -12.96 & \ \ -13.02\\
\end{tabular}
\label{pmeShift}
\end{center}
\end{minipage}
\end{table*}

\section{Conclusions}

The free energy for proton ordered variants of hexagonal and cubic ice
$I$, ice B, and recently discovered Ice-{\it i} where calculated under
standard conditions for several common water models via thermodynamic
integration. All the water models studied show Ice-{\it i} to be the
minimum free energy crystal structure in the with a 9 \AA\ switching
function cutoff. Calculated melting and boiling points show
surprisingly good agreement with the experimental values; however, the
solid phase at 1 atm is Ice-{\it i}, not ice $I_h$. The effect of
interaction truncation was investigated through variation of the
cutoff radius, use of a reaction field parameterized model, and
estimation of the results in the presence of the Ewald summation
correction. Interaction truncation has a significant effect on the
computed free energy values, but Ice-{\it i} is still observed to be a
relavent ice polymorph in simulation studies.

\section{Acknowledgments}
Support for this project was provided by the National Science
Foundation under grant CHE-0134881. Computation time was provided by
the Notre Dame High Performance Computing Cluster and the Notre Dame
Bunch-of-Boxes (B.o.B) computer cluster (NSF grant DMR-0079647).

\newpage

\bibliographystyle{jcp}
\bibliography{iceiPaper}


\end{document}
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#	Content
1	%\documentclass[prb,aps,twocolumn,tabularx]{revtex4}
2	\documentclass[preprint,aps,endfloats]{revtex4}
3	%\documentclass[11pt]{article}
4	%\usepackage{endfloat}
5	\usepackage{amsmath}
6	\usepackage{epsf}
7	\usepackage{berkeley}
8	%\usepackage{setspace}
9	%\usepackage{tabularx}
10	\usepackage{graphicx}
11	%\usepackage[ref]{overcite}
12	%\pagestyle{plain}
13	%\pagenumbering{arabic}
14	%\oddsidemargin 0.0cm \evensidemargin 0.0cm
15	%\topmargin -21pt \headsep 10pt
16	%\textheight 9.0in \textwidth 6.5in
17	%\brokenpenalty=10000
18
19	%\renewcommand\citemid{\ } % no comma in optional reference note
20
21	\begin{document}
22
23	\title{A Free Energy Study of Low Temperature and Anomolous Ice}
24
25	\author{Christopher J. Fennell and J. Daniel Gezelter{\thefootnote}
26	\footnote[1]{Corresponding author. \ Electronic mail: gezelter@nd.edu}}
27
28	\address{Department of Chemistry and Biochemistry\\ University of Notre Dame\\
29	Notre Dame, Indiana 46556}
30
31	\date{\today}
32
33	%\maketitle
34	%\doublespacing
35
36	\begin{abstract}
37	\end{abstract}
38
39	\maketitle
40
41	\newpage
42
43	%\narrowtext
44
45	%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%
46	% BODY OF TEXT
47	%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%
48
49	\section{Introduction}
50
51	\section{Methods}
52
53	Canonical ensemble (NVT) molecular dynamics calculations were
54	performed using the OOPSE (Object-Oriented Parallel Simulation Engine)
55	molecular mechanics package. All molecules were treated as rigid
56	bodies, with orientational motion propogated using the symplectic DLM
57	integration method. Details about the implementation of these
58	techniques can be found in a recent publication.\cite{Meineke05}
59
60	Thermodynamic integration was utilized to calculate the free energy of
61	several ice crystals at 200 K using the TIP3P, TIP4P, TIP5P, SPC/E,
62	SSD/RF, and SSD/E water models. Liquid state free energies at 300 and
63	400 K for all of these water models were also determined using this
64	same technique, in order to determine melting points and generate
65	phase diagrams. All simulations were carried out at densities
66	resulting in a pressure of approximately 1 atm at their respective
67	temperatures.
68
69	A single thermodynamic integration involves a sequence of simulations
70	over which the system of interest is converted into a reference system
71	for which the free energy is known. This transformation path is then
72	integrated in order to determine the free energy difference between
73	the two states:
74	\begin{equation}
75	\begin{center}
76	\Delta A = \int_0^1\left\langle\frac{\partial V(\lambda
77	)}{\partial\lambda}\right\rangle_\lambda d\lambda,
78	\end{center}
79	\end{equation}
80	where $V$ is the interaction potential and $\lambda$ is the
81	transformation parameter. Simulations are distributed unevenly along
82	this path in order to sufficiently sample the regions of greatest
83	change in the potential. Typical integrations in this study consisted
84	of $\sim$25 simulations ranging from 300 ps (for the unaltered system)
85	to 75 ps (near the reference state) in length.
86
87	For the thermodynamic integration of molecular crystals, the Einstein
88	Crystal is chosen as the reference state that the system is converted
89	to over the course of the simulation. In an Einstein Crystal, the
90	molecules are harmonically restrained at their ideal lattice locations
91	and orientations. The partition function for a molecular crystal
92	restrained in this fashion has been evaluated, and the Helmholtz Free
93	Energy ({\it A}) is given by
94	\begin{eqnarray}
95	A = E_m\ -\ kT\ln \left (\frac{kT}{h\nu}\right )^3&-&kT\ln \left
96	[\pi^\frac{1}{2}\left (\frac{8\pi^2I_\mathrm{A}kT}{h^2}\right
97	)^\frac{1}{2}\left (\frac{8\pi^2I_\mathrm{B}kT}{h^2}\right
98	)^\frac{1}{2}\left (\frac{8\pi^2I_\mathrm{C}kT}{h^2}\right
99	)^\frac{1}{2}\right ] \nonumber \\ &-& kT\ln \left [\frac{kT}{2(\pi
100	K_\omega K_\theta)^{\frac{1}{2}}}\exp\left
101	(-\frac{kT}{2K_\theta}\right)\int_0^{\left (\frac{kT}{2K_\theta}\right
102	)^\frac{1}{2}}\exp(t^2)\mathrm{d}t\right ],
103	\label{ecFreeEnergy}
104	\end{eqnarray}
105	where $2\pi\nu = (K_\mathrm{v}/m)^{1/2}$.\cite{Baez95a} In equation
106	\ref{ecFreeEnergy}, $K_\mathrm{v}$, $K_\mathrm{\theta}$, and
107	$K_\mathrm{\omega}$ are the spring constants restraining translational
108	motion and deflection of and rotation around the principle axis of the
109	molecule respectively (Fig. \ref{waterSpring}), and $E_m$ is the
110	minimum potential energy of the ideal crystal. In the case of
111	molecular liquids, the ideal vapor is chosen as the target reference
112	state.
113	\begin{figure}
114	\includegraphics[scale=1.0]{rotSpring.eps}
115	\caption{Possible orientational motions for a restrained molecule.
116	$\theta$ angles correspond to displacement from the body-frame {\it
117	z}-axis, while $\omega$ angles correspond to rotation about the
118	body-frame {\it z}-axis. $K_\theta$ and $K_\omega$ are spring
119	constants for the harmonic springs restraining motion in the $\theta$
120	and $\omega$ directions.}
121	\label{waterSpring}
122	\end{figure}
123
124	Charge, dipole, and Lennard-Jones interactions were modified by a
125	cubic switching between 100\% and 85\% of the cutoff value (9 \AA ). By
126	applying this function, these interactions are smoothly truncated,
127	thereby avoiding poor energy conserving dynamics resulting from
128	harsher truncation schemes. The effect of a long-range correction was
129	also investigated on select model systems in a variety of manners. For
130	the SSD/RF model, a reaction field with a fixed dielectric constant of
131	80 was applied in all simulations.\cite{Onsager36} For a series of the
132	least computationally expensive models (SSD/E, SSD/RF, and TIP3P),
133	simulations were performed with longer cutoffs of 12 and 15 \AA\ to
134	compare with the 9 \AA\ cutoff results. Finally, results from the use
135	of an Ewald summation were estimated for TIP3P and SPC/E by performing
136	calculations with Particle-Mesh Ewald (PME) in the TINKER molecular
137	mechanics software package. TINKER was chosen because it can also
138	propogate the motion of rigid-bodies, and provides the most direct
139	comparison to the results from OOPSE. The calculated energy difference
140	in the presence and absence of PME was applied to the previous results
141	in order to predict changes in the free energy landscape.
142
143	\section{Results and discussion}
144
145	The free energy of proton ordered Ice-{\it i} was calculated and
146	compared with the free energies of proton ordered variants of the
147	experimentally observed low-density ice polymorphs, $I_h$ and $I_c$,
148	as well as the higher density ice B, observed by B\`{a}ez and Clancy
149	and thought to be the minimum free energy structure for the SPC/E
150	model at ambient conditions (Table \ref{freeEnergy}).\cite{Baez95b}
151	Ice XI, the experimentally observed proton ordered variant of ice
152	$I_h$, was investigated initially, but it was found not to be as
153	stable as antiferroelectric variants of proton ordered or even proton
154	disordered ice$I_h$.\cite{Davidson84} The proton ordered variant of
155	ice $I_h$ used here is a simple antiferroelectric version that has an
156	8 molecule unit cell. The crystals contained 648 or 1728 molecules for
157	ice B, 1024 or 1280 molecules for ice $I_h$, 1000 molecules for ice
158	$I_c$, or 1024 molecules for Ice-{\it i}. The larger crystal sizes
159	were necessary for simulations involving larger cutoff values.
160
161	\begin{table*}
162	\begin{minipage}{\linewidth}
163	\renewcommand{\thefootnote}{\thempfootnote}
164	\begin{center}
165	\caption{Calculated free energies for several ice polymorphs with a
166	variety of common water models. All calculations used a cutoff radius
167	of 9 \AA\ and were performed at 200 K and $\sim$1 atm. Units are
168	kcal/mol. *Ice $I_c$ is unstable at 200 K using SSD/RF.}
169	\begin{tabular}{ l c c c c }
170	\hline \\[-7mm]
171	\ \quad \ Water Model\ \ & \ \quad \ \ \ \ $I_h$ \ \ & \ \quad \ \ \ \ $I_c$ \ \ & \ \quad \ \ \ \ B \ \ & \ \quad \ \ \ Ice-{\it i} \ \quad \ \\
172	\hline \\[-3mm]
173	\ \quad \ TIP3P & \ \quad \ -11.41 & \ \quad \ -11.23 & \ \quad \ -11.82 & \quad -12.30\\
174	\ \quad \ TIP4P & \ \quad \ -11.84 & \ \quad \ -12.04 & \ \quad \ -12.08 & \quad -12.33\\
175	\ \quad \ TIP5P & \ \quad \ -11.85 & \ \quad \ -11.86 & \ \quad \ -11.96 & \quad -12.29\\
176	\ \quad \ SPC/E & \ \quad \ -12.67 & \ \quad \ -12.96 & \ \quad \ -13.25 & \quad -13.55\\
177	\ \quad \ SSD/E & \ \quad \ -11.27 & \ \quad \ -11.19 & \ \quad \ -12.09 & \quad -12.54\\
178	\ \quad \ SSD/RF & \ \quad \ -11.51 & \ \quad \ NA* & \ \quad \ -12.08 & \quad -12.29\\
179	\end{tabular}
180	\label{freeEnergy}
181	\end{center}
182	\end{minipage}
183	\end{table*}
184
185	The free energy values computed for the studied polymorphs indicate
186	that Ice-{\it i} is the most stable state for all of the common water
187	models studied. With the free energy at these state points, the
188	temperature and pressure dependence of the free energy was used to
189	project to other state points and build phase diagrams. Figures
190	\ref{tp3phasedia} and \ref{ssdrfphasedia} are example diagrams built
191	from the free energy results. All other models have similar structure,
192	only the crossing points between these phases exist at different
193	temperatures and pressures. It is interesting to note that ice $I$
194	does not exist in either cubic or hexagonal form in any of the phase
195	diagrams for any of the models. For purposes of this study, ice B is
196	representative of the dense ice polymorphs. A recent study by Sanz
197	{\it et al.} goes into detail on the phase diagrams for SPC/E and
198	TIP4P in the high pressure regime.\cite{Sanz04}
199	\begin{figure}
200	\includegraphics[width=\linewidth]{tp3PhaseDia.eps}
201	\caption{Phase diagram for the TIP3P water model in the low pressure
202	regime. The displayed $T_m$ and $T_b$ values are good predictions of
203	the experimental values; however, the solid phases shown are not the
204	experimentally observed forms. Both cubic and hexagonal ice $I$ are
205	higher in energy and don't appear in the phase diagram.}
206	\label{tp3phasedia}
207	\end{figure}
208	\begin{figure}
209	\includegraphics[width=\linewidth]{ssdrfPhaseDia.eps}
210	\caption{Phase diagram for the SSD/RF water model in the low pressure
211	regime. Calculations producing these results were done under an
212	applied reaction field. It is interesting to note that this
213	computationally efficient model (over 3 times more efficient than
214	TIP3P) exhibits phase behavior similar to the less computationally
215	conservative charge based models.}
216	\label{ssdrfphasedia}
217	\end{figure}
218
219	\begin{table*}
220	\begin{minipage}{\linewidth}
221	\renewcommand{\thefootnote}{\thempfootnote}
222	\begin{center}
223	\caption{Melting ($T_m$), boiling ($T_b$), and sublimation ($T_s$)
224	temperatures of several common water models compared with experiment.}
225	\begin{tabular}{ l c c c c c c c }
226	\hline \\[-7mm]
227	\ \ Equilibria Point\ \ & \ \ \ \ \ TIP3P \ \ & \ \ \ \ \ TIP4P \ \ & \ \quad \ \ \ \ TIP5P \ \ & \ \ \ \ \ SPC/E \ \ & \ \ \ \ \ SSD/E \ \ & \ \ \ \ \ SSD/RF \ \ & \ \ \ \ \ Exp. \ \ \\
228	\hline \\[-3mm]
229	\ \ $T_m$ (K) & \ \ 269 & \ \ 265 & \ \ 271 & 297 & \ \ - & \ \ 278 & \ \ 273\\
230	\ \ $T_b$ (K) & \ \ 357 & \ \ 354 & \ \ 337 & 396 & \ \ - & \ \ 349 & \ \ 373\\
231	\ \ $T_s$ (K) & \ \ - & \ \ - & \ \ - & - & \ \ 355 & \ \ - & \ \ -\\
232	\end{tabular}
233	\label{meltandboil}
234	\end{center}
235	\end{minipage}
236	\end{table*}
237
238	Table \ref{meltandboil} lists the melting and boiling temperatures
239	calculated from this work. Surprisingly, most of these models have
240	melting points that compare quite favorably with experiment. The
241	unfortunate aspect of this result is that this phase change occurs
242	between Ice-{\it i} and the liquid state rather than ice $I_h$ and the
243	liquid state. These results are actually not contrary to previous
244	studies in the literature. Earlier free energy studies of ice $I$
245	using TIP4P predict a $T_m$ ranging from 214 to 238 K (differences
246	being attributed to choice of interaction truncation and different
247	ordered and disordered molecular arrangements). If the presence of ice
248	B and Ice-{\it i} were omitted, a $T_m$ value around 210 K would be
249	predicted from this work. However, the $T_m$ from Ice-{\it i} is
250	calculated at 265 K, significantly higher in temperature than the
251	previous studies. Also of interest in these results is that SSD/E does
252	not exhibit a melting point at 1 atm, but it shows a sublimation point
253	at 355 K. This is due to the significant stability of Ice-{\it i} over
254	all other polymorphs for this particular model under these
255	conditions. While troubling, this behavior turned out to be
256	advantagious in that it facilitated the spontaneous crystallization of
257	Ice-{\it i}. These observations provide a warning that simulations of
258	SSD/E as a ``liquid'' near 300 K are actually metastable and run the
259	risk of spontaneous crystallization. However, this risk changes when
260	applying a longer cutoff.
261
262	\begin{figure}
263	\includegraphics[width=\linewidth]{cutoffChange.eps}
264	\caption{Free energy as a function of cutoff radius for (A) SSD/E, (B)
265	TIP3P, and (C) SSD/RF. Data points omitted include SSD/E: $I_c$ 12
266	\AA\, TIP3P: $I_c$ 12 \AA\ and B 12 \AA\, and SSD/RF: $I_c$ 9
267	\AA\. These crystals are unstable at 200 K and rapidly convert into a
268	liquid. The connecting lines are qualitative visual aid.}
269	\label{incCutoff}
270	\end{figure}
271
272	Increasing the cutoff radius in simulations of the more
273	computationally efficient water models was done in order to evaluate
274	the trend in free energy values when moving to systems that do not
275	involve potential truncation. As seen in Fig. \ref{incCutoff}, the
276	free energy of all the ice polymorphs show a substantial dependence on
277	cutoff radius. In general, there is a narrowing of the free energy
278	differences while moving to greater cutoff radius. This trend is much
279	more subtle in the case of SSD/RF, indicating that the free energies
280	calculated with a reaction field present provide a more accurate
281	picture of the free energy landscape in the absence of potential
282	truncation.
283
284	To further study the changes resulting to the inclusion of a
285	long-range interaction correction, the effect of an Ewald summation
286	was estimated by applying the potential energy difference do to its
287	inclusion in systems in the presence and absence of the
288	correction. This was accomplished by calculation of the potential
289	energy of identical crystals with and without PME using TINKER. The
290	free energies for the investigated polymorphs using the TIP3P and
291	SPC/E water models are shown in Table \ref{pmeShift}. TIP4P and TIP5P
292	are not fully supported in TINKER, so the results for these models
293	could not be estimated. The same trend pointed out through increase of
294	cutoff radius is observed in these results. Ice-{\it i} is the
295	preferred polymorph at ambient conditions for both the TIP3P and SPC/E
296	water models; however, there is a narrowing of the free energy
297	differences between the various solid forms. In the case of SPC/E this
298	narrowing is significant enough that it becomes less clear cut that
299	Ice-{\it i} is the most stable polymorph, and is possibly metastable
300	with respect to ice B and possibly ice $I_c$. However, these results
301	do not significantly alter the finding that the Ice-{\it i} polymorph
302	is a stable crystal structure that should be considered when studying
303	the phase behavior of water models.
304
305	\begin{table*}
306	\begin{minipage}{\linewidth}
307	\renewcommand{\thefootnote}{\thempfootnote}
308	\begin{center}
309	\caption{The free energy of the studied ice polymorphs after applying
310	the energy difference attributed to the inclusion of the PME
311	long-range interaction correction. Units are kcal/mol.}
312	\begin{tabular}{ l c c c c }
313	\hline \\[-7mm]
314	\ \ Water Model \ \ & \ \ \ \ \ $I_h$ \ \ & \ \ \ \ \ $I_c$ \ \ & \ \quad \ \ \ \ B \ \ & \ \ \ \ \ Ice-{\it i} \ \ \\
315	\hline \\[-3mm]
316	\ \ TIP3P & \ \ -11.53 & \ \ -11.24 & \ \ -11.51 & \ \ -11.67\\
317	\ \ SPC/E & \ \ -12.77 & \ \ -12.92 & \ \ -12.96 & \ \ -13.02\\
318	\end{tabular}
319	\label{pmeShift}
320	\end{center}
321	\end{minipage}
322	\end{table*}
323
324	\section{Conclusions}
325
326	The free energy for proton ordered variants of hexagonal and cubic ice
327	$I$, ice B, and recently discovered Ice-{\it i} where calculated under
328	standard conditions for several common water models via thermodynamic
329	integration. All the water models studied show Ice-{\it i} to be the
330	minimum free energy crystal structure in the with a 9 \AA\ switching
331	function cutoff. Calculated melting and boiling points show
332	surprisingly good agreement with the experimental values; however, the
333	solid phase at 1 atm is Ice-{\it i}, not ice $I_h$. The effect of
334	interaction truncation was investigated through variation of the
335	cutoff radius, use of a reaction field parameterized model, and
336	estimation of the results in the presence of the Ewald summation
337	correction. Interaction truncation has a significant effect on the
338	computed free energy values, but Ice-{\it i} is still observed to be a
339	relavent ice polymorph in simulation studies.
340
341	\section{Acknowledgments}
342	Support for this project was provided by the National Science
343	Foundation under grant CHE-0134881. Computation time was provided by
344	the Notre Dame High Performance Computing Cluster and the Notre Dame
345	Bunch-of-Boxes (B.o.B) computer cluster (NSF grant DMR-0079647).
346
347	\newpage
348
349	\bibliographystyle{jcp}
350	\bibliography{iceiPaper}
351
352
353	\end{document}