13 |
|
\newlabel{eq:Kc}{{3}{3}} |
14 |
|
\newlabel{eq:Kh}{{4}{3}} |
15 |
|
\gdef \LT@i {\LT@entry |
16 |
< |
{1}{88.82234pt}\LT@entry |
17 |
< |
{1}{83.13188pt}\LT@entry |
18 |
< |
{1}{83.13188pt}} |
16 |
> |
{1}{80.25342pt}\LT@entry |
17 |
> |
{1}{53.69913pt}\LT@entry |
18 |
> |
{1}{72.96097pt}} |
19 |
|
\@writefile{toc}{\contentsline {section}{\numberline {3}Tests and Applications}{4}} |
20 |
|
\@writefile{toc}{\contentsline {subsection}{\numberline {3.1}Thermal conductivities}{4}} |
21 |
|
\@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.}}{4}} |
22 |
|
\newlabel{table:goldconductivity}{{1}{4}} |
23 |
|
\gdef \LT@ii {\LT@entry |
24 |
< |
{1}{88.82234pt}\LT@entry |
25 |
< |
{1}{83.13188pt}\LT@entry |
26 |
< |
{1}{83.13188pt}} |
24 |
> |
{1}{80.25342pt}\LT@entry |
25 |
> |
{1}{53.69913pt}\LT@entry |
26 |
> |
{1}{72.96097pt}} |
27 |
|
\@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 ambient density.}}{5}} |
28 |
|
\newlabel{table:waterconductivity}{{2}{5}} |
29 |
|
\@writefile{toc}{\contentsline {subsection}{\numberline {3.2}Shear viscosity}{5}} |
30 |
|
\@writefile{toc}{\contentsline {subsection}{\numberline {3.3}Interfacial thermal conductance}{5}} |
31 |
|
\@writefile{toc}{\contentsline {subsection}{\numberline {3.4}Interfacial friction}{5}} |
32 |
< |
\newlabel{eq:fr}{{5}{5}} |
32 |
> |
\newlabel{eq:Xi}{{5}{6}} |
33 |
> |
\newlabel{eq:S}{{6}{6}} |
34 |
> |
\newlabel{eq:Xia}{{7}{6}} |
35 |
> |
\newlabel{eq:Xibc}{{8}{6}} |
36 |
|
\gdef \LT@iii {\LT@entry |
37 |
< |
{1}{120.12054pt}\LT@entry |
38 |
< |
{1}{97.35826pt}\LT@entry |
39 |
< |
{1}{91.6678pt}\LT@entry |
40 |
< |
{1}{83.13188pt}\LT@entry |
41 |
< |
{1}{83.13188pt}} |
42 |
< |
\newlabel{eq:fa}{{6}{6}} |
43 |
< |
\newlabel{eq:fb}{{7}{6}} |
44 |
< |
\@writefile{lot}{\contentsline {table}{\numberline {3}{\ignorespaces Calculated interfacial friction coefficients ($\kappa $) and slip length ($\delta $) of gold nanostructures solvated in TraPPE-UA hexane. The ellipsoid is oriented with the long axis along the $z$ direction.}}{6}} |
45 |
< |
\newlabel{table:interfacialfriction}{{3}{6}} |
46 |
< |
\@writefile{toc}{\contentsline {section}{\numberline {4}Discussion}{6}} |
37 |
> |
{1}{92.33887pt}\LT@entry |
38 |
> |
{1}{87.99518pt}\LT@entry |
39 |
> |
{1}{81.23506pt}\LT@entry |
40 |
> |
{1}{81.23506pt}\LT@entry |
41 |
> |
{1}{33.27168pt}\LT@entry |
42 |
> |
{1}{57.0pt}} |
43 |
> |
\gdef \LT@iv {\LT@entry |
44 |
> |
{1}{92.33887pt}\LT@entry |
45 |
> |
{1}{87.99518pt}\LT@entry |
46 |
> |
{1}{81.23506pt}\LT@entry |
47 |
> |
{1}{81.23506pt}} |
48 |
> |
\@writefile{lot}{\contentsline {table}{\numberline {3}{\ignorespaces Calculated ``stick'' interfacial friction coefficients ($\kappa $) and friction factors ($f$) of gold nanostructures solvated in TraPPE-UA hexane. The ellipsoid is oriented with the long axis along the $z$ direction.}}{7}} |
49 |
> |
\newlabel{table:interfacialfriction}{{3}{7}} |
50 |
> |
\@writefile{lot}{\contentsline {table}{\numberline {4}{\ignorespaces Calculated ``slip'' interfacial friction coefficients ($\kappa $) and friction factors ($f$) of gold nanostructures solvated in TraPPE-UA hexane. The ellipsoid is oriented with the long axis along the $z$ direction.}}{7}} |
51 |
> |
\newlabel{table:interfacialfriction}{{4}{7}} |
52 |
> |
\@writefile{toc}{\contentsline {section}{\numberline {4}Discussion}{8}} |
53 |
|
\bibdata{acs-nonperiodicVSS,nonperiodicVSS} |