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\title{Do the facets of ice $I_\mathrm{h}$ crystals have different |
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friction coefficients? Simulating shear in ice/water interfaces} |
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\author{P. B. Louden} |
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\author{J. Daniel Gezelter} |
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\email{gezelter@nd.edu} |
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\affiliation[University of Notre Dame]{251 Nieuwland Science Hall\\ |
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Department of Chemistry and Biochemistry\\ University of Notre |
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Dame\\ Notre Dame, Indiana 46556} |
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\keywords{} |
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\begin{document} |
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\begin{abstract} |
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We have investigated the structural properties of the basal and |
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prismatic facets of an SPC/E model of the ice Ih / water interface |
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when the solid phase is being drawn through liquid water (i.e. sheared |
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relative to the fluid phase). To impose the shear, we utilized a |
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reverse non-equilibrium molecular dynamics (RNEMD) method that creates |
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non-equilibrium conditions using velocity shearing and scaling (VSS) |
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moves of the molecules in two physically separated slabs in the |
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simulation cell. This method can create simultaneous temperature and |
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velocity gradients and allow the measurement of friction transport |
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properties at interfaces. We present calculations of the interfacial |
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friction coefficients and the apparent independence of shear rate on |
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interfacial width and show that water moving over a flat ice/water |
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interface is close to the no-slip boundary condition. |
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\end{abstract} |
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\newpage |
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\section{Introduction} |
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%-----Outline of Intro--------------- |
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% in general, ice/water interface is important b/c .... |
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% here are some people who have worked on ice/water, trying to understand the processes above .... |
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% with the recent development of VSS-RNEMD, we can now look at the shearing problem |
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% talk about what we will present in this paper |
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% -------End Intro------------------ |
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%Gay02: cites many other ice/water papers, make sure to cite them. |
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Understanding the ice/water interface is essential for explaining complex processes such as nucleartion and crystal growth\cite{Han92,Granasy95,Vanfleet95}, crystal melting\cite{Weber83,Han92,Sakai96,Sakai96B}, and biological interfacial processes, such as the antifreeze protein found in winter flounder\cite{Wierzbicki07, Chapsky97}. These processes have been studied at the fundamental level of the ice/water interface by several groups, including studying the structure and width of the interface. Haymet \emph{et al.} have done extensive work on ice Ih, the most common form of ice on Earth, including characterizing and determining the width of the ice/water interface for the SPC, SPC/E, CF1, and TIP4P models for water. \cite{Karim87,Karim88,Karim90,Hayward01,Bryk02,Hayward02,Gay02} More recently, Haymet \emph{et al.} have been investigating the effects cations and anions have on crystal nucleation\cite{Bryk04,Smith05,Wilson08,Wilson10}. Nada \emph{et al.} have also studied the ice/water interface\cite{Nada95,Nada00,Nada03,Nada12}. They have found that the different facets of ice Ih have different growth rates, primarily, that the prismatic facet grows faster than the basal facet due to the mechanism of the crystal growth being the reordering of the hydrogen bonding network\cite{Nada05}. |
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Another complex process which requires investigation at the ice/water interface is the movement of water over ice, such as icebergs floating in the ocean. In addition to understanding the structure and width of the interface, it is pertinent to understand the friction caused by the shearing of water across the ice to understand this process. However, until recently, simulations of this nature were not possible. |
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With the recent development of velocity shearing and scaling reverse non-equilibrium molecular dynamics (VSS-RNEMD), it is now possible to calculate transport properties from heterogeneous systems.\cite{Kuang12} This method can create simultaneous temperature and velocity gradients and allow the measurement of friction and thermal transport properties at interfaces. This allows for the study of the width of the ice/water interface as the ice is sheared through the liquid, while imposing a thermal gradient to prevent frictional heating of the interface. In this paper, we investigate the width and the friction coefficient of the ice/water interface as the ice is sheared through the liquid under a weak thermal gradient. |
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\section{Methodology} |
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\subsection{Stable ice I$_\mathrm{h}$ / water interfaces} |
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The structure of ice I$_\mathrm{h}$ is well understood; it |
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crystallizes in a hexagonal space group P$6_3/mmc$, and the hexagonal |
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crystals of ice have two faces that are commonly exposed, the basal |
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face $\{0~0~0~1\}$, which forms the top and bottom of each hexagonal |
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plate, and the prismatic $\{1~0~\bar{1}~0\}$ face which forms the |
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sides of the plate. Other less-common, but still important, faces of |
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ice I$_\mathrm{h}$ are the secondary prism face, $\{1~1~\bar{2}~0\}$, |
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and the prismatic face, $\{2~0~\bar{2}~1\}$. |
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Ice I$_\mathrm{h}$ is normally proton disordered in bulk crystals, |
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although the surfaces probably have a preference for proton ordering |
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along strips of dangling H-atoms and Oxygen lone |
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pairs.\cite{Buch:2008fk} |
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For small simulated ice interfaces, it is useful to have a |
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proton-ordered, but zero-dipole crystal that exposes these strips of |
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dangling H-atoms and lone pairs. Also, if we're going to place |
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another material in contact with one of the ice crystalline planes, it |
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is useful to have an orthorhombic (rectangular) box to work with. A |
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recent paper by Hirsch and Ojam\"{a}e describes how to create |
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proton-ordered bulk ice I$_\mathrm{h}$ in alternative orthorhombic |
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cells.\cite{Hirsch04} |
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|
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We are using Hirsch and Ojam\"{a}e's structure 6 which is an |
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orthorhombic cell ($P2_12_12_1$) that produces a proton-ordered |
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version of ice Ih. Table \ref{tab:equiv} contains a mapping between |
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the Miller indices in the P$6_3/mmc$ crystal system and those in the |
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Hirsch and Ojam\"{a}e $P2_12_12_1$ system. |
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\begin{wraptable}{r}{3.5in} |
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\begin{tabular}{|ccc|} \hline |
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& hexagonal & orthorhombic \\ |
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& ($P6_3/mmc$) & ($P2_12_12_1$) \\ |
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crystal face & Miller indices & equivalent \\ \hline |
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basal & $\{0~0~0~1\}$ & $\{0~0~1\}$ \\ |
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prism & $\{1~0~\bar{1}~0\}$ & $\{1~0~0\}$ \\ |
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secondary prism & $\{1~1~\bar{2}~0\}$ & $\{1~3~0\}$ \\ |
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pryamidal & $\{2~0~\bar{2}~1\}$ & $\{2~0~1\}$ \\ \hline |
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\end{tabular} |
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\end{wraptable} |
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Structure 6 from the Hirsch and Ojam\"{a}e paper has lattice |
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parameters $a = 4.49225$, $b = 7.78080$, $c = 7.33581$ and two water |
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molecules whose atoms reside at the following fractional coordinates: |
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\begin{wraptable}{r}{3.25in} |
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\begin{tabular}{|ccccc|} \hline |
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atom label & type & x & y & z \\ \hline |
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O$_{a}$ & O & 0.75 & 0.1667 & 0.4375 \\ |
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H$_{1a}$ & H & 0.5735 & 0.2202 & 0.4836 \\ |
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H$_{2a}$ & H & 0.7420 & 0.0517 & 0.4836 \\ |
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O$_{b}$ & O & 0.25 & 0.6667 & 0.4375 \\ |
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H$_{1b}$ & H & 0.2580 & 0.6693 & 0.3071 \\ |
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H$_{2b}$ & H & 0.4265 & 0.7255 & 0.4756 \\ \hline |
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\end{tabular} |
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\end{wraptable} |
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To construct the basal and prismatic interfaces, the crystallographic |
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coordinates above were used to construct an orthorhombic unit cell |
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which was then replicated in all three dimensions yielding a |
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proton-ordered block of ice I$_{h}$. To expose the desired face, the |
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orthorhombic representation was then cut along the ($001$) or ($100$) |
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planes for the basal and prismatic faces respectively. The resulting |
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block was rotated so that the exposed faces were aligned with the $z$ |
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axis normal to the exposed face. The block was then cut along two |
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perpendicular directions in a way that allowed for perfect periodic |
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replication in the $x$ and $y$ axes, creating a slab with either the |
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basal or prismatic faces exposed along the $z$ axis. The slab was |
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then replicated in the $x$ and $y$ dimensions until a desired sample |
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size was obtained. |
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Although experimental solid/liquid coexistant temperature under normal |
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pressure are close to 273K, Haymet \emph{et al.} have done extensive |
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work on characterizing the ice/water |
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interface.\cite{Karim88,Karim90,Hayward01,Bryk02,Hayward02} They have |
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found for the SPC/E water model,\cite{Berendsen87} which is also used |
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in this study, the ice/water interface is most stable at |
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225$\pm$5K.\cite{Bryk02} To create a ice / water interface, a box of |
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liquid water that had the same dimensions in $x$ and $y$ was |
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equilibrated at 225 K and 1 atm of pressure in the NPAT ensemble (with |
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the $z$ axis allowed to fluctuate to equilibrate to the correct |
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pressure). The liquid and solid systems were combined by carving out |
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any water molecule from the liquid simulation cell that was within 3 |
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\AA\ of any atom in the ice slab. |
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Molecular translation and orientational restraints were applied in the |
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early stages of equilibration to prevent melting of the ice slab. |
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These restraints were removed during NVT equilibration, well before |
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data collection was carried out. |
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\subsection{Shearing ice / water interfaces without bulk melting} |
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As one drags a solid through a liquid, there will be frictional |
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heating that will act to melt the interface. To study the frictional |
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behavior of the interface without causing the interface to melt, it is |
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necessary to apply a weak thermal gradient along with the momentum |
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gradient. This can be accomplished with of the newly-developed |
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approaches to reverse non-equilibrium molecular dynamics (RNEMD). The |
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velocity shearing and scaling (VSS) variant of RNEMD utilizes a series |
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of simultaneous velocity exchanges between two regions within the |
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simulation cell.\cite{Kuang12} One of these regions is centered within |
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the ice slab, while the other is centrally located in the liquid phase |
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region. VSS-RNEMD provides a set of conservation constraints for |
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simultaneously creating either a momentum flux or a thermal flux (or |
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both) between the two slabs. Satisfying the constraint equations |
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ensures that the new configurations are sampled from the same NVE |
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ensemble as previously. |
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The VSS moves are applied periodically to scale and shift the particle |
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velocities ($\mathbf{v}_i$ and $\mathbf{v}_j$) in two slabs ($H$ and |
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$C$) which are separated by half of the simulation box, |
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\begin{displaymath} |
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\begin{array}{rclcl} |
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& \underline{\mathrm{shearing}} & & |
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\underline{~~~~~~~~~~~~\mathrm{scaling}~~~~~~~~~~~~} \\ |
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\mathbf{v}_i \leftarrow & |
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\mathbf{a}_c\ & + & c\cdot\left(\mathbf{v}_i - \langle\mathbf{v}_c |
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\rangle\right) + \langle\mathbf{v}_c\rangle \\ |
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\mathbf{v}_j \leftarrow & |
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\mathbf{a}_h & + & h\cdot\left(\mathbf{v}_j - \langle\mathbf{v}_h |
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\rangle\right) + \langle\mathbf{v}_h\rangle . |
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\end{array} |
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\end{displaymath} |
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Here $\langle\mathbf{v}_c\rangle$ and $\langle\mathbf{v}_h\rangle$ are |
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the center of mass velocities in the $C$ and $H$ slabs, respectively. |
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Within the two slabs, particles receive incremental changes or a |
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``shear'' to their velocities. The amount of shear is governed by the |
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imposed momentum flux, $\mathbf{j}_z(\mathbf{p})$ |
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\begin{eqnarray} |
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\mathbf{a}_c & = & - \mathbf{j}_z(\mathbf{p}) \Delta t / M_c \label{vss1}\\ |
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\mathbf{a}_h & = & + \mathbf{j}_z(\mathbf{p}) \Delta t / M_h \label{vss2} |
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\end{eqnarray} |
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where $M_{\{c,h\}}$ is the total mass of particles within each of the |
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slabs and $\Delta t$ is the interval between two separate operations. |
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To simultaneously impose a thermal flux ($J_z$) between the slabs we |
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use energy conservation constraints, |
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\begin{eqnarray} |
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K_c - J_z\Delta t & = & c^2 (K_c - \frac{1}{2}M_c \langle\mathbf{v}_c |
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\rangle^2) + \frac{1}{2}M_c (\langle \mathbf{v}_c \rangle + \mathbf{a}_c)^2 \label{vss3}\\ |
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K_h + J_z\Delta t & = & h^2 (K_h - \frac{1}{2}M_h \langle\mathbf{v}_h |
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\rangle^2) + \frac{1}{2}M_h (\langle \mathbf{v}_h \rangle + |
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\mathbf{a}_h)^2 \label{vss4}. |
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\label{constraint} |
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\end{eqnarray} |
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Simultaneous solution of these quadratic formulae for the scaling |
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coefficients, $c$ and $h$, will ensure that the simulation samples from |
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the original microcanonical (NVE) ensemble. Here $K_{\{c,h\}}$ is the |
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instantaneous translational kinetic energy of each slab. At each time |
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interval, it is a simple matter to solve for $c$, $h$, $\mathbf{a}_c$, |
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and $\mathbf{a}_h$, subject to the imposed momentum flux, |
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$j_z(\mathbf{p})$, and thermal flux, $J_z$, values. Since the VSS |
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operations do not change the kinetic energy due to orientational |
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degrees of freedom or the potential energy of a system, configurations |
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after the VSS move have exactly the same energy (and linear |
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momentum) as before the move. |
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As the simulation progresses, the VSS moves are performed on a regular |
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basis, and the system develops a thermal and/or velocity gradient in |
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response to the applied flux. In a bulk material it is quite simple |
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to use the slope of the temperature or velocity gradients to obtain |
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the thermal conductivity or shear viscosity. |
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The VSS-RNEMD approach is versatile in that it may be used to |
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implement thermal and shear transport simultaneously. Perturbations |
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of velocities away from the ideal Maxwell-Boltzmann distributions are |
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minimal, as is thermal anisotropy. This ability to generate |
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simultaneous thermal and shear fluxes has been previously utilized to |
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map out the shear viscosity of SPC/E water over a wide range of |
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temperatures (90~K) with a single 1 ns simulation.\cite{Kuang12} |
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Here we are using this method primarily to generate a shear between |
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the ice slab and the liquid phase, while using a weak thermal gradient |
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to maintaining the interface at the 225K target value. This will |
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insure minimal melting of the bulk ice phase and allows us to control |
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the exact temperature of the interface. |
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\subsection{Computational Details} |
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All simulations were performed using OpenMD with a time step of 2 fs, |
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and periodic boundary conditions in all three dimensions. The systems |
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were divided into 100 artificial bins along the $z$-axis for the |
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VSS-RNEMD moves, which were attempted every 50 fs. The gradients were |
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allowed to develop for 1 ns before data collection was began. Once |
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established, four successive 0.5 ns runs were performed for each shear rate. During these simulations, snapshots of the system were taken every 1 ps, and the |
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average velocities and densities of each bin were accumulated every |
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attempted VSS-RNEMD move. |
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|
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%A paragraph on the equilibration procedure of the system? Shenyu did some amount of equilibration to the files and then I was handed them. I performed 5 ns of NVT at 225K for both systems, then 5 ns of NVE at 225K for both systems, with no gradients imposed. |
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%For the basal, once the thermal gradient was found which gave me the interfacial temperature I wanted (-2.0E-6 kcal/mol/A^2/fs), I equilibrated the file for 5 ns letting this gradient stabilize. Then I continued to use this thermal gradient as I imposed momentum gradients and watched the response of the interface. |
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%For the prismatic, a gradient was not found that would give me the interfacial temperature I desired, so while imposing a thermal gradient that had the interface at 220K, I raised the temperature of the system to 230K. This resulted in a thermal gradient which gave my interface at 225K, equilibrated for ins NVT, then ins NVE while this gradient was still imposed, then I began dragging. |
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%I have run each system for 1 ns under PTgrads to allow them to develop, then ran each system for an additional 2 ns in segments of 0.5 ns in order to calculate statistics of the calculated values. |
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\section{Results and discussion} |
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\subsection{Measuring the Width of the Interface} |
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\subsubsection{Tetrahedrality Order Parameter} |
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Any parameter or function that varies across the interface from a bulk liquid value to a solid value can be used as a measure of the width of the interface. However, due to the VSS-RNEMD moves pertrurbing the momentum of the molecules, parameters such as the translational order parameter and the diffusion order parameter may be artifically skewed. A structural parameter such as the pairwise correlation function would not be influenced by the perturbations. Here, the local order tetraherdal parameter as described by Kumar\cite{Kumar09} and |
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Errington\cite{Errington01} was used as a measure of the interfacial width. |
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The local tetrahedral order parameter, $q$, is given by |
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\begin{equation} |
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q_{k} \equiv 1 -\frac{3}{8}\sum_{i=1}^{3} \sum_{j=i+1}^{4} \Bigg[\cos\psi_{ikj}+\frac{1}{3}\Bigg]^2 |
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\end{equation} |
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where $\psi_{ikj}$ is the angle formed by the oxygen sites on molecule $k$, and the oxygen site on its two closest neighbors, molecules $i$ and $j$. The local tetrahedral order parameter function has a range of (0,1), where the larger the value $q$ has the more tetrahedral the ordering of the local environment is. A $q$ value of one describes a perfectly tetrahedral environment relative to it and its four nearest neighbors, and the parameter's value decreases as the local ordering becomes less tetrahedral. |
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|
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%If the central water molecule has a perfect tetrahedral geometry with its four nearest neighbors, the parameter goes to one, and decreases to zero as the geometry deviates from the ideal configuration. |
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|
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The system was divided into 100 bins of length $L$ along the $z$-axis, and a cutoff radius for the neighboring molecules was set to 3.41 \AA\ . A $q_{z}$ value was then determined by averaging the $q$ values for each molecule in the bin. |
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\begin{equation} |
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q_{z} \equiv \int_0^L \Bigg[1 -\frac{3}{8}\sum_{i=1}^{3} \sum_{j=i+1}^{4} \bigg[\cos\psi_{ikj}+\frac{1}{3}\bigg]^2\Bigg]\delta(z_{k}-z)\mathrm{d}z |
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\end{equation} |
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The $q_{z}$ values for each snapshot were then averaged to give an average tetrahedrality profile of the system about the $z$- axis. The profile was then fit with a hyperbolic tangent function given by |
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\begin{equation}\label{tet_fit} |
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q_{z} \approx q_{liq}+\frac{q_{ice}-q_{liq}}{2}(\tanh(\alpha(z-I_{L,m}))-\tanh(\alpha(z-I_{R,m})))+\beta|(z-z_{mid})| |
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\end{equation} |
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|
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where $q_{liq}$ and $q_{ice}$ are fitting parameters for the local tetrahedral order parameter for the liquid and ice, $\alpha$ is proportional to the inverse of the width of the interface, and $I_{L,m}$ and $I_{R,m}$ are the midpoints of the left and right interface. The last term in \ref{tet_fit} accounts for the influence the thermal gradient has on the tetrahedrality profile in the liquid region; here $\beta$ is a fitting parameter and $z_{mid}$ is the midpoint of the z dimension of the simulation box. |
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|
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In Figures \ref{fig:bComic} and \ref{fig:pComic} we see the $z$-dimensional profiles for several parameters for the basal and prismatic systems. In panel (a) of the figures we see the tetrahedrality profile of the systems (black circles). In the liquid region of the system, the local tetrahedral order parameter is approximately 0.75 while in the solid region the parameter is approximately 0.94, indicating a more tetrahedral structure of the water molecules. The hyperbolic tangent function used to fit the tetrahedrality profiles is in red and the verticle dotted lines denote the midpoint of the interfaces. The weak thermal gradient applied to the systems in order to keep the interface at a stable temperature, 225$\pm$5K, can be seen in panel (b). Lastly, the velocity gradient across the systems can be seen in panel (c). From panel (c), we can see liquid phase water molecules 10 \AA\ to 15 \AA\ from the midpoint of the interfaces are being dragged along with the ice block, indicating that the shearing of ice water is in the stick boundary condition. |
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\begin{figure} |
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\includegraphics[width=\linewidth]{bComicStrip} |
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\caption{\label{fig:bComic} The basal system: (a) The local tetrahedral order parameter,$q$, (black circles) fit by a hyperbolic tangent (red line), (b) the thermal gradient imposed on the system to maintain a stable interfacial temperature, and (c) the velocity gradient imposed on the system. The verticle dotted lines indicate the midpoint of the interfaces.} |
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\end{figure} |
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\begin{figure} |
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\includegraphics[width=\linewidth]{pComicStrip} |
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\caption{\label{fig:pComic} The prismatic system: (a) The local tetrahedral order parameter,$q$, (black circles) fit by a hyperbolic tangent (red line), (b) the thermal gradient imposed on the system to maintain a stable interfacial temperature, and (c) the velocity gradient imposed on the system.The verticle dotted lines indicate the midpoint of the interfaces.} |
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\end{figure} |
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From the tetrahedrality fits, we found the interfacial width for the basal and prismatic systems to be 3.2$\pm$0.4 \AA\ and 3.6$\pm$0.2 \AA\ with no applied momentum flux. Over the range of shear rates investigated, 0.6$\pm$0.3 ms\textsuperscript{-1} to 5.3$\pm$0.5 ms\textsuperscript{-1} for the basal system and 0.9$\pm$0.2 ms\textsuperscript{-1} to 4.5$\pm$0.1 ms\textsuperscript{-1}, there was no appreciable change in the interface width found. The calculated values for the interfacial width over all shear rates investigated contained the control values within their error bars. |
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|
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\subsubsection{Orientational Time Correlation Function} |
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The orientational time correlation function (OTCF) gives insight of the local environment of molecules. The rate at which the function decays corresponds to how hindered the motions of a molecule are. The more hindered a molecules motion is the slower the function will decay, and the function decays more rapidly for molecules with less constrained motions. |
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\begin{equation}\label{C(t)1} |
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C_{2}(t)=\langle P_{2}(\mathbf{v}_{i}(t)\mathbf{v}_{i}(t=0))\rangle |
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\end{equation} |
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In \eqref{C(t)1}, $P_{2}$ is the Legendre polynomial of the second order and $\mathbf{v}_{i}$ is the bisecting unit vector of the $i$th water molecule in the lab frame. |
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|
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Here, we are evaluating this function across the $z$-dimension of the system as another measure of the change in the local environment and behavior of water molecules from the liquid region to the slushy interfacial region. After each of the 0.5 ns simulations with an applied shear and the control simulations, the simulations were run for an additional 200 ps where the positions of every molecule in the system were recorded every 0.1 ps. The systems were then divided into 30 bins and the OTCF was evaluated for each bin. |
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|
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It has been shown that the OTCF for water can be fit by a triexponential decay\cite{Furse08}, where the three components of the decay correspond to a fast (<200 fs) reorientational piece driven by the restoring forces of existing hydrogen bonds, a middle (on the order of several ps) piece describing the large angle jumps that occur during the breaking and formation of new hydrogen bonds\cite{Laage08,Laage11}, and a slow (on the order of hundreds of ps) contribution describing the translational motion of the molecules. The OTCF data for each bin were pruned to 100 ps, and fit to the triexponential decay |
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\begin{equation} |
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C_{2}(t)=a_{1}e^{-t/\tau_{short}}+a_{2}e^{-t/\tau_{middle}}+a_{3}e^{-t/\tau_{long}}+a_{4} |
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\end{equation} |
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where $a_{1}+a_{2}+a_{3}+a_{4}=1$. An average value and standard deviation for each $\tau$ was obtained for each bin from the four runs. Lastly, the means and standard deviations were averaged about the center of the system. |
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|
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\begin{figure} |
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\includegraphics[width=\linewidth]{basal_Tau_comic_strip} |
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\caption{\label{fig:basal_Tau_comic_strip} The orientational time correlation function for the basal system fit by the triexponential decay $a_{1}e^{-t/\tau_{short}}+a_{2}e^{-t/\tau_{middle}}+a_{3}e^{-t/\tau_{long}}+a_{4}$ where $a_{1}+a_{2}+a_{3}+a_{4}=1$. The verticle dotted line indicates the average midpoint of the interface as determined by the tetrahedrality fit. In (b) and (c) $\tau_{middle}$ and $\tau_{long}$ have a consistent value of about 5.5 ps and 50 ps in the liquid region, and increase in value approaching the interface. $\tau_{middle}$ corresponds to the breaking and making of hydrogen bonds as explained by extended jump model proposed by Laage and Hynes\cite{Laage08,Laage11} and $\tau_{long}$ relates to the translational motion of the molecules. In (a), we see that $\tau_{short}$ has a value of about 71 fs in the liquid region, and decreases in value approaching the interface. This component of the decay corresponds to the reorientational forces of existing hydrogen bonds on the inertial rotational of the molecules. Thus $\tau_{short}$ decreases approaching the interface due to the hindered range of motion of the molecules. } |
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\end{figure} |
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|
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\begin{figure} |
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\includegraphics[width=\linewidth]{prismatic_Tau_comic_strip} |
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\caption{\label{fig:prismatic_Tau_comic_strip} The orientational time correlation function for the prismatic system fit by the triexponential decay $a_{1}e^{-t/\tau_{short}}+a_{2}e^{-t/\tau_{middle}}+a_{3}e^{-t/\tau_{long}}+a_{4}$ where $a_{1}+a_{2}+a_{3}+a_{4}=1$. The verticle dotted line indicates the average midpoint of the interface as determined by the tetrahedrality fit. In (b) and (c) $\tau_{middle}$ and $\tau_{long}$ have a consistent value of about 3.5 ps and 30 ps in the liquid region, and increase in value approaching the interface. $\tau_{middle}$ corresponds to the breaking and making of hydrogen bonds as explained by extended jump model proposed by Laage and Hynes\cite{Laage08,Laage11} and $\tau_{long}$ relates to the translational motion of the molecules. In (a), we see that $\tau_{short}$ has a value of about 73 fs in the liquid region, and decreases in value approaching the interface. This component of the decay corresponds to the reorientational forces of existing hydrogen bonds on the inertial rotational of the molecules. Thus $\tau_{short}$ decreases approaching the interface due to the hindered range of motion of the molecules.} |
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\end{figure} |
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|
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Figures \ref{fig:basal_Tau_comic_strip} and \ref{fig:prismatic_Tau_comic_strip} plots the decomposition of the OTCF at varying displacements from the center of the ice for the basal and prismatic systems. We see in (a) $\tau_{short}$, (b) $\tau_{middle}$, and (c) $\tau_{long}$ for the control system (no applied momentum flux) in black, and a system with a large shear rate in red. The verticle dotted lines at a displacement of about 17 \AA\ and 9 \AA\ denote the midpoints of the interfaces as determined by the hyperbolic tangent fit of the tetrahedrality profile. |
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|
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In panels (a), we see at large displacements from the center of the ice $\tau_{short}$ for the basal system has a value of about 71 fs and 72 fs for the prismatic. Decreasing in displacement from about 26 \AA\ to about 19 \AA\ in the basal system, the value of $\tau_{short}$ decreases to about 63 fs. Likewise, $\tau_{short}$ decreases to about 63 fs from roughly 20 \AA\ to 12 \AA\. This is due to the increasingly constrained motion of the water molecules as we approach the interface. In panels (b), $\tau_{middle}$ at large displacements from the ice has a value of about 5.5 ps and 3 ps for the basal and prismatic systems. We find $\tau_{middle}$ increases in value as we approach the interface in both cases. This component of the decay corresponds to the rearrangement of the hydrogen bonding network, which takes longer as the molecules motion becomes more constrained. In panels (c), $\tau_{long}$ has a value of about 50 ps for the basal and roughly 30 ps for the prismatic at large displacements from the interface. Similar to $\tau_{middle}$, $\tau_{long}$ also increases in value as we approach the interface for both systems. It is also apparent that shearing the ice water has no effect on the orientational decay time, or on any of the decomposed components. |
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|
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For each system, there is an apparent approximate value for $\tau_{short}$, $\tau_{middle}$, and $\tau_{long}$ at large displacements from the interface. There also appears to be a single displacement, $d_{basal}$ or $d_{prismatic}$, from the interface at which all three decay times begin to deviate from their bulk liquid values. We found $d_{basal}$ and $d_{prismatic}$ to be roughly 15 \AA\ and 8 \AA\ respectively. These two results indicate that the dynamics of the water molecules within $d_{basal}$ and $d_{prismatic}$ are being significantly perturbed by the ice and/or the interface, even though the structural width of the interface by analysis of the tetrahedrality profile indicates that bulk liquid structure of water is recovered in about 4 \AA\ from the edge of the ice. |
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Beaglehole and Wilson have measured the ice/water interface to have a thickness approximately 10 \AA\ for both the basal and prismatic face of ice by ellipticity measurements \cite{Beaglehole93}. Structurally, we have found the basal and prismatic interfacial width to be 3.2$\pm$0.4 \AA\ and 3.6$\pm$0.2 \AA\ . However, we have shown through decomposition of the OTCF a much larger interfacial region. |
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\subsection{Coefficient of Friction of the Interface} |
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As the ice is sheared through the liquid, there will be a friction between the ice and The interface. Balasubramanian has shown how to calculate the coefficient of friction for a solid-liquid interface. \cite{Balasubramanian99} |
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\begin{equation} |
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\langle F_{x}^{w}\rangle(t)=-S\lambda_{wall}v_{x}(y_{wall}) |
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\end{equation} |
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In this equation, $F_{x}^{w}$ is the total force of all the atoms acting on the fluid, $S$ is the surface area the force is being applied upon, $\lambda_{wall}$ is the coefficient of friction of the interface, and $v_{x}(y_{wall})$ is the velocity at the displacement from the interface at which the hydrodynamics breaks down. Since the total force imposed momentum flux, $J_{z}(p_{x})$, is known in the VSS-RNEMD simulations, |
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\section{Conclusion} |
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Here we have simulated the basal and prismatic facets of an SPC/E model of the ice Ih / water interface. Using VSS-RNEMD, the ice was sheared relative to the liquid while imposed thermal gradients kept the interface at a stable temperature. Caculation of the local tetrahedrality order parameter has shown an appearant independence of the shear rate on the interfacial width. The coefficient of friction of the interface was also calculated for each of the facets. The $\lambda_{wall}$ for the basal face was calculated to be , and for the prismatic facet. For both facets, the shearing ice water was found to be in the no-slip boundary condition. |
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\begin{acknowledgement} |
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Support for this project was provided by the National Science |
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Foundation under grant CHE-0848243. Computational time was provided |
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by the Center for Research Computing (CRC) at the University of |
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Notre Dame. |
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\end{acknowledgement} |
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\newpage |
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\bibstyle{achemso} |
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\bibliography{iceWater} |
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\begin{tocentry} |
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\begin{wrapfigure}{l}{0.5\textwidth} |
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\begin{center} |
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\includegraphics[width=\linewidth]{SystemImage.png} |
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\end{center} |
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\end{wrapfigure} |
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An image of our system. |
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\end{tocentry} |
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\end{document} |
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%************************************************************** |
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%Non-mass weighted slopes (amu*Angstroms^-2 * fs^-1) |
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% basal: slope=0.090677616, error in slope = 0.003691743 |
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%prismatic: slope = 0.050101506, error in slope = 0.001348181 |
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%Mass weighted slopes (Angstroms^-2 * fs^-1) |
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%basal slope = 4.76598E-06, error in slope = 1.94037E-07 |
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%prismatic slope = 3.23131E-06, error in slope = 8.69514E-08 |
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%************************************************************** |