--- trunk/nonperiodicVSS/nonperiodicVSS.aux	2014/01/17 19:45:57	4003
+++ trunk/nonperiodicVSS/nonperiodicVSS.aux	2014/01/17 22:44:07	4004
@@ -59,15 +59,13 @@
 \newlabel{eq:Xistick}{{10}{7}}
 \newlabel{eq:S}{{11}{7}}
 \newlabel{eq:Xia}{{12}{7}}
-\newlabel{eq:Xibc}{{13}{7}}
 \citation{Kuang2012}
 \citation{Zwanzig}
 \citation{Zwanzig}
 \citation{Kuang2010}
+\newlabel{eq:Xibc}{{13}{8}}
 \newlabel{eq:Xieff}{{14}{8}}
 \newlabel{eq:tau}{{15}{8}}
-\@writefile{toc}{\contentsline {section}{\numberline {4}Tests and Applications}{8}}
-\@writefile{toc}{\contentsline {subsection}{\numberline {4.1}Thermal conductivities}{8}}
 \gdef \LT@i {\LT@entry 
     {1}{69.5093pt}\LT@entry 
     {1}{51.0pt}\LT@entry 
@@ -77,23 +75,24 @@
 \citation{Romer2012,Zhang2005}
 \citation{WagnerKruse}
 \citation{WagnerKruse}
+\@writefile{toc}{\contentsline {section}{\numberline {4}Tests and Applications}{9}}
+\@writefile{toc}{\contentsline {subsection}{\numberline {4.1}Thermal conductivities}{9}}
+\@writefile{lot}{\contentsline {table}{\numberline {1}{\ignorespaces Calculated thermal conductivity of a crystalline gold nanoparticle of radius 40 \r A. Calculations were performed at 300 K and ambient density. Gold-gold interactions are described by the Quantum Sutton-Chen potential.}}{9}}
+\newlabel{table:goldTC}{{1}{9}}
 \citation{Zhang2005}
 \citation{Romer2012}
 \citation{WagnerKruse}
-\@writefile{lot}{\contentsline {table}{\numberline {1}{\ignorespaces Calculated thermal conductivity of a crystalline gold nanoparticle of radius 40 \r A. Calculations were performed at 300 K and ambient density. Gold-gold interactions are described by the Quantum Sutton-Chen potential.}}{9}}
-\newlabel{table:goldTC}{{1}{9}}
 \gdef \LT@ii {\LT@entry 
     {1}{81.01138pt}\LT@entry 
     {1}{51.0pt}\LT@entry 
     {1}{58.6495pt}}
+\@writefile{lot}{\contentsline {table}{\numberline {2}{\ignorespaces Calculated thermal conductivity of a cluster of 6912 SPC/E water molecules. Calculations were performed at 300 K and 5 atm.}}{10}}
+\newlabel{table:waterTC}{{2}{10}}
+\@writefile{toc}{\contentsline {subsection}{\numberline {4.2}Interfacial thermal conductance}{10}}
 \gdef \LT@iii {\LT@entry 
     {1}{110.31483pt}\LT@entry 
     {1}{71.7394pt}\LT@entry 
     {1}{0.0pt}}
-\@writefile{lot}{\contentsline {table}{\numberline {2}{\ignorespaces Calculated thermal conductivity of a cluster of 6912 SPC/E water molecules. Calculations were performed at 300 K and 5 atm.}}{10}}
-\newlabel{table:waterTC}{{2}{10}}
-\@writefile{toc}{\contentsline {subsection}{\numberline {4.2}Interfacial thermal conductance}{10}}
-\@writefile{lot}{\contentsline {table}{\numberline {3}{\ignorespaces Calculated interfacial thermal conductance ($G$) values for gold nanoparticles of varying radii solvated in explicit TraPPE-UA hexane. The nanoparticle $G$ values are compared to previous results for a gold slab in TraPPE-UA hexane, revealing increased interfacial thermal conductance for non-planar interfaces.}}{10}}
 \gdef \LT@iv {\LT@entry 
     {1}{96.74344pt}\LT@entry 
     {1}{92.00313pt}\LT@entry 
@@ -101,10 +100,11 @@
     {1}{64.79945pt}\LT@entry 
     {1}{64.79945pt}\LT@entry 
     {1}{64.43709pt}}
+\@writefile{lot}{\contentsline {table}{\numberline {3}{\ignorespaces Calculated interfacial thermal conductance ($G$) values for gold nanoparticles of varying radii solvated in explicit TraPPE-UA hexane. The nanoparticle $G$ values are compared to previous results for a Au(111) interface in TraPPE-UA hexane, revealing increased interfacial thermal conductance for non-planar interfaces.}}{11}}
 \newlabel{table:interfacialconductance}{{3}{11}}
 \@writefile{toc}{\contentsline {subsection}{\numberline {4.3}Interfacial friction}{11}}
 \@writefile{lot}{\contentsline {table}{\numberline {4}{\ignorespaces Comparison of rotational friction coefficients under ideal ``slip'' ($\Xi ^{rr}_{\mathit  {slip}}$) and ``stick'' conditions ($\Xi ^{rr}_{\mathit  {stick}}$) and effective rotational friction coefficients ($\Xi ^{rr}_{\mathit  {eff}}$) of gold nanostructures solvated in TraPPE-UA hexane at 230 K. The ellipsoid is oriented with the long axis along the $z$ direction.}}{11}}
-\newlabel{table:couple}{{4}{11}}
+\newlabel{table:couple}{{4}{12}}
 \@writefile{toc}{\contentsline {section}{\numberline {5}Discussion}{12}}
 \bibdata{acs-nonperiodicVSS,nonperiodicVSS}
 \bibcite{ASHURST:1975tg}{{1}{1975}{{Ashurst and Hoover}}{{Ashurst, and Hoover}}}