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\begin{document} |
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\title{Is the Ewald summation still necessary? \\ |
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Pairwise alternatives to the accepted standard for \\ |
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Pairwise alternatives to the accepted standard for |
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long-range electrostatics in molecular simulations} |
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\author{Christopher J. Fennell and J. Daniel Gezelter\footnote{Corresponding author. \ Electronic mail: |
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\date{\today} |
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\maketitle |
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\doublespacing |
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\begin{abstract} |
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We investigate pairwise electrostatic interaction methods and show |
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differences. |
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Results and discussion for the individual analysis of each of the |
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system types appear in the supporting information, while the |
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cumulative results over all the investigated systems appears below in |
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section \ref{sec:EnergyResults}. |
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system types appear in the supporting information,\cite{EPAPSdeposit} |
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while the cumulative results over all the investigated systems appears |
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below in section \ref{sec:EnergyResults}. |
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\subsection{Molecular Dynamics and the Force and Torque Vectors}\label{sec:MDMethods} |
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We evaluated the pairwise methods (outlined in section |
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significant improvement using the group-switched cutoff because the |
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salt and salt solution systems contain non-neutral groups. Interested |
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readers can consult the accompanying supporting information for a |
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comparison where all groups are neutral. |
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comparison where all groups are neutral.\cite{EPAPSdeposit} |
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For the {\sc sp} method, inclusion of electrostatic damping improves |
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the agreement with Ewald, and using an $\alpha$ of 0.2 \AA $^{-1}$ |
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particles in all seven systems, while torque vectors are only |
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available for neutral molecular groups. Damping is more beneficial to |
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charged bodies, and this observation is investigated further in the |
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accompanying supporting information. |
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accompanying supporting information.\cite{EPAPSdeposit} |
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Although not discussed previously, group based cutoffs can be applied |
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to both the {\sc sp} and {\sc sf} methods. The group-based cutoffs |
