621 |
|
called the average surface area per lipid. Constat area and constant |
622 |
|
lateral pressure simulation can be achieved by extending the |
623 |
|
standard NPT ensemble with a different pressure control strategy |
624 |
+ |
|
625 |
|
\begin{equation} |
626 |
< |
\dot |
627 |
< |
\mathord{\buildrel{\lower3pt\hbox{$\scriptscriptstyle\leftrightarrow$}} |
628 |
< |
\over \eta } _{\alpha \beta } = \left\{ \begin{array}{l} |
629 |
< |
\frac{{V(P_{\alpha \beta } - P_{{\rm{target}}} )}}{{\tau _{\rm{B}}^{\rm{2}} fk_B T_{{\rm{target}}} }}{\rm{ }}(\alpha = \beta = z), \\ |
630 |
< |
0{\rm{ }}(\alpha \ne z{\rm{ }}or{\rm{ }}\beta \ne z) \\ |
631 |
< |
\end{array} \right. |
631 |
< |
\label{methodEquation:NPATeta} |
626 |
> |
\.{\overleftrightarrow{{\eta _{\alpha \beta}}}}=\left\{\begin{array}{ll} |
627 |
> |
\frac{{V(P_{\alpha \beta } - P_{{\rm{target}}} )}}{{\tau_{\rm{B}}^{\rm{2}} fk_B T_{{\rm{target}}} }} |
628 |
> |
& \mbox{if \[ \alpha = \beta = z)$}\\ |
629 |
> |
0 & \mbox{otherwise}\\ |
630 |
> |
\end{array} |
631 |
> |
\right. |
632 |
|
\end{equation} |
633 |
+ |
|
634 |
|
Note that the iterative schemes for NPAT are identical to those |
635 |
|
described for the NPTi integrator. |
636 |
|
|
649 |
|
pressure. The equation of motion for cell size control tensor, |
650 |
|
$\eta$, in $NP\gamma T$ is |
651 |
|
\begin{equation} |
652 |
< |
\dot |
653 |
< |
\mathord{\buildrel{\lower3pt\hbox{$\scriptscriptstyle\leftrightarrow$}} |
654 |
< |
\over \eta } _{\alpha \beta } = \left\{ \begin{array}{l} |
655 |
< |
- A_{xy} (\gamma _\alpha - \gamma _{{\rm{target}}} ){\rm{ (}}\alpha = \beta = x{\rm{ or }} = y{\rm{)}} \\ |
656 |
< |
\frac{{V(P_{\alpha \beta } - P_{{\rm{target}}} )}}{{\tau _{\rm{B}}^{\rm{2}} fk_B T_{{\rm{target}}} }}{\rm{ }}(\alpha = \beta = z) \\ |
656 |
< |
0{\rm{ }}(\alpha \ne \beta ) \\ |
657 |
< |
\end{array} \right. |
658 |
< |
\label{methodEquation:NPrTeta} |
652 |
> |
\.{\overleftrightarrow{{\eta _{\alpha \beta}}}}=\left\{\begin{array}{ll} |
653 |
> |
- A_{xy} (\gamma _\alpha - \gamma _{{\rm{target}}} ) & \mbox{$\alpha = \beta = x$ or $\alpha = \beta = y$}\\ |
654 |
> |
\frac{{V(P_{\alpha \beta } - P_{{\rm{target}}} )}}{{\tau _{\rm{B}}^{\rm{2}} fk_B T_{{\rm{target}}}}} & \mbox{$\alpha = \beta = z$} \\ |
655 |
> |
0 & \mbox{$\alpha \ne \beta$} \\ |
656 |
> |
\right. |
657 |
|
\end{equation} |
658 |
|
where $ \gamma _{{\rm{target}}}$ is the external surface tension and |
659 |
|
the instantaneous surface tensor $\gamma _\alpha$ is given by |