383 |
|
\begin{figure} |
384 |
|
\includegraphics[width=\linewidth]{defDelta} |
385 |
|
\caption{The slip length $\delta$ can be obtained from a velocity |
386 |
< |
profile of a solid-liquid interface. An example of Au/hexane |
387 |
< |
interfaces is shown.} |
386 |
> |
profile of a solid-liquid interface simulation. An example of |
387 |
> |
Au/hexane interfaces is shown. Calculation for the left side is |
388 |
> |
illustrated. The right side is similar to the left side.} |
389 |
|
\label{slipLength} |
390 |
|
\end{figure} |
391 |
|
|
668 |
|
Solid & Liquid & $T$ & $j_z(p_x)$ & $\eta_{liquid}$ & $\kappa$ |
669 |
|
& $\delta$ & $G$\footnote{References \cite{kuang:AuThl} and |
670 |
|
\cite{kuang:164101}.} \\ |
671 |
< |
surface & model & K & MPa & mPa$\cdot$s & Pa$\cdot$s/m & nm & |
672 |
< |
MW/m$^2$/K \\ |
671 |
> |
surface & molecules & K & MPa & mPa$\cdot$s & Pa$\cdot$s/m & nm |
672 |
> |
& MW/m$^2$/K \\ |
673 |
|
\hline |
674 |
|
Au(111) & hexane & 200 & 1.08 & 0.20() & 5.3$\times$10$^4$() & |
675 |
|
3.7 & 46.5 \\ |