Difference between revisions of "Solution details"
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the solution of the zenith angle direction is the Legendre polynomial if it satisfied the following condition: | the solution of the zenith angle direction is the Legendre polynomial if it satisfied the following condition: | ||
− | <math>\frac {1}{sin\theta} \frac{\partial{}}{\partial{\theta}} sin\theta\frac{\partial{V}}{\partial{\theta}} = R_k(r') \frac {1}{\mu} [ | + | <math>\frac {1}{sin\theta} \frac{\partial{}}{\partial{\theta}} sin\theta\frac{\partial{V}}{\partial{\theta}} = R_k(r') \frac {1}{\mu} \left [ \frac{d}{d \mu} (1- \mu^2) \frac{d{P_k(\mu)}}{d{\mu}} \right] = -k(k+1) P_k(\mu) </math> |
Revision as of 22:20, 25 October 2013
asymptotic solution details for Boltzmann equation for a hole has a uniform electric field
n + - n = 0
Steps to solve Boltzmann equation
for the previous equation let consider the asymptotic solution has the form:
so
where
and
In spherical coordinates:
which is symmetric in direction.
the solution of the zenith angle direction is the Legendre polynomial if it satisfied the following condition: