|
|
| Line 55: |
Line 55: |
| | ===Solution Analysis=== | | ===Solution Analysis=== |
| | | | |
| − | The general form of hte previous equation and its solution are defined as the following: | + | The general form of the previous equation and its solution are defined as the following: |
| − | | |
| | | | |
| | + | <math> \frac{d^2 y}{dx} +\frac{1-2\alpha}{x} \frac{dy}{dx}-\left [ \frac{\nu^2 \gamma^2 - \alpha^2)}{x^2} + (\beta \gamma x^{\gamma - 1})^2 \right]y = 0 </math> |
| | | | |
| | | | |
Revision as of 20:09, 26 October 2013
Asymptotic solution details for Boltzmann equation for a hole has a uniform electric field
[math] (\frac {\partial^2{}}{\partial{x^2}} +\frac {\partial^2{}}{\partial{x^2}})[/math]n +
[math] D_L \frac {\partial^2{}}{\partial{z^2}}[/math] -
[math] W \frac {\partial{}}{\partial{z}}[/math] n = 0
Steps to solve Boltzmann equation <ref name="Huxley"> Huxley, L. G. H. Leonard George Holden, The diffusion and drift of electrons in gases, John Wiley and sons, 1974 , call number QC793.5.E628 H89 </ref>
for the previous equation let consider the asymptotic solution has the form:
[math] n(x', y', z') = e^{\lambda_L z'} V(x,y,z) [/math]
so
[math] \nabla'^2 V = \lambda_L^2 V [/math]
where
[math] \nabla'^2 V = \frac {\partial^2{}}{\partial{x'^2}} + \frac {\partial^2{}}{\partial{y'^2}} + \frac {\partial^2{}}{\partial{z^2}}[/math]
and
[math] x' = \frac {D_L}{D} x [/math]
[math] y' = \frac {D_L}{D} y [/math]
In spherical coordinates:
[math] \frac {1}{r'^2} \frac{\partial{}}{\partial{r'}}r'^2 \frac{\partial{V}}{\partial{r'}} + \frac {1}{r'^2 sin\theta'} \frac{\partial{}}{\partial{\theta}} sin\theta \frac{\partial{V}}{\partial{\theta}} = \lambda_L^2 V [/math]
which is symmetric in [math]\phi[/math] direction.
Assuming [math]V(r',\theta) = R_k(r')P_k(\mu) [/math]the solution of the zenith angle direction is the Legendre polynomial, and can be written as:
[math]\frac {1}{r'sin\theta} \frac{\partial{}}{\partial{\theta}} sin\theta\frac{\partial{V}}{\partial{\theta}} = R_k(r') \frac{d}{d \mu} \left [ (1- \mu^2) \frac{d{P_k(\mu)}}{d{\mu}} \right] [/math]
and
[math] \frac{d}{d \mu} \left [ (1- \mu^2) \frac{d{P_k(\mu)}}{d{\mu}} \right]= -k(k+1) P_k(\mu) [/math]
so,
[math] \frac {1}{r'^2} \frac{d}{dr'}\left (r'^2 \frac{dR_k}{dr'}\right) - \left [ \frac{k(k+1)}{r'^2} +\lambda_L^2 \right]R_k = \frac{d^2 R_k}{dr'^2} +\frac{2}{r'} \frac{dR_k}{dr'}-\left [ \frac{k(k+1)}{r'^2} +\lambda_L^2 \right]R_k = 0 [/math]
The modified Bessel functions, first and second kind, are the solutions for the previous equation but the boundary conditions determines which one to use, in this case [math] r'\rightarrow 0[/math],
[math] n \rightarrow \infty [/math], and
[math] n \rightarrow 0 [/math] as
[math] r'\rightarrow \infty [/math].
so only the modified Bessel of second kind K_k are the non-zaro terms. so the the general solution for the equation can be written as :
[math] V= R_k (r') Pk(\mu) = \exp{(\lambda_L z)}\sum_{k=0}^{\infty} A_k r'^{-1/2} K_{k+1/2} (\lambda_L r') P_k(\mu) [/math]
Solution Analysis
The general form of the previous equation and its solution are defined as the following:
[math] \frac{d^2 y}{dx} +\frac{1-2\alpha}{x} \frac{dy}{dx}-\left [ \frac{\nu^2 \gamma^2 - \alpha^2)}{x^2} + (\beta \gamma x^{\gamma - 1})^2 \right]y = 0 [/math]
The previous solution bcan be written as
<references/>
GO BACK [1]