Summary of Nanowire Growth Mechanism: Difference between revisions

From Micro and Nano Mechanics Group
Jump to navigation Jump to search
Line 11: Line 11:
<math> V_L=\frac{\pi}{3}(\frac{r}{sin(\beta)})^3(1-cos(\beta))^2(2+cos(\beta))</math>
<math> V_L=\frac{\pi}{3}(\frac{r}{sin(\beta)})^3(1-cos(\beta))^2(2+cos(\beta))</math>


Force balance is always kept as
Force balance is always kept as,


<math> \sigma_{LV} cos(\beta) = \sigma_{SV} cos(\alpha)-\sigma_{LS} </math>
<math> \sigma_{LV} cos(\beta) = \sigma_{SV} cos(\alpha)-\sigma_{LS} </math>

<math> tan(\alpha)=-\frac{dh}{dr} </math>

<math> h(\alpha')=-\int_0^{\alpha'}{tan(\alpha)\frac{dr}{d\alpha}d\alpha},V_L = const </math>


==Anisotropic Material Nanowire Statics==
==Anisotropic Material Nanowire Statics==

Revision as of 19:42, 26 June 2012

Summary of Nanowire Growth Mechanism

Yanming Wang and Seunghwa Ryu

Isotropic Material Nanowire Statics

No line tension at trijunction

Force balance is always kept as,

Anisotropic Material Nanowire Statics

Isotropic Material Nanowire Growth Dynamics

Anisotropic Material Nanowire Growth Dynamics