Ink diffusing in water - partial diff equations

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Homework Statement



The particles of an ink blob dropped into a large container of water diffuse outward and obey the radial diffusion equation:

dn/dt = (D/r2) (d/dr) (r2* (dn/dr) )

where n(r,t) is the density of ink particles at point r at time t and D is the diffusion constant.

Verify, by direct differentiation that:

ns = N*(1 / (4*pi*D*t) )3/2 * er2/4Dt

is a solution of this equation and satisfies the condition that the total number of ink particles is N for any value of t.

Homework Equations


The Attempt at a Solution



I have no idea?
 
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No idea...? Not so good!
For
[tex] n_s(r,t)=N\frac{e^{r^2/4Dt}}{(4\pi Dt)^{3/2}}[/tex]
what is
[tex] \frac{d}{dt}n_s(r,t)[/tex],
[tex] \frac{d}{dr}n_s(r,t)[/tex]
and
[tex] \frac{d^2}{dr^2}n_s(r,t)[/tex]
?
Do these expression satisfy
[tex] \frac{d}{dt}n_s(r,t)=\frac{D}{r^2}\frac{d}{dr}\left[r^2\frac{d}{dr}n_s(r,t)\right]=\frac{D}{r^2}\left[2r\frac{d}{dr}n_s(r,t)+r^2\frac{d^2}{dr^2}n_s(r,t)\right\[/tex]?
 
I did it :D
I won't type it all out because it would take forever, but I got both sides of the equation to equal :)
 
Congratulations, no need to type it all out. :smile: