Elements of plasma kinetic theory, Bittencourt

Fernando Mourao
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Homework Statement


Consider the motion of charged particles, in one dimension only, in
the presence of an electric potential V ( x). Show, by direct substitution,
that a function of the form

f=f(1/mv^2 + qV)

is a solution of the Boltzmann equation under steady-state conditions.

Homework Equations



∂f/∂t + v⋅∇f + a[∇][/v]f = 0

a= dv/dt
v=dr/dt

The Attempt at a Solution


[/B]
I've been having problems with mathematical demonstrations due to lack of practice in the past 6 years. Any steering into the correct direction would be greatly appreciated.
 
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You simply need to replace the f in the left-hand-side of the Boltzmann equation with the function that was given and show that result is indeed 0. Since this is in 1D only, then ∇ = d/dx.
 
DrClaude said:
You simply need to replace the f in the left-hand-side of the Boltzmann equation with the function that was given and show that result is indeed 0. Since this is in 1D only, then ∇ = d/dx.
Thank you for your reply Dr Claude.

I understand the process of direct substitution and the fact that, in this case, ∇ = d/dx and ∇v=d/dvx.
But my problem is the mathematical proof. How to explicitly show that:

∂/∂t(f(½mv2+qV)) + v⋅∂/∂x(f(½mv2+qV)) + a⋅∂/∂vx(f(½mv2+qV))=0

v and a being vectors.
 

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