- #1
homology
- 305
- 1
Hi folks, I'm drawing a blank on the following:
<br /> \frac{1}{r^2}\frac{\partial}{\partial r}r^2\frac{\partial \phi}{\partial r}+\mu^2 \phi=0<br />
I 'know' the solutions which are linear combinations of e^{\pm\mu r}/r as you can check, but I've been trying to see if I could show the fact (as opposed to just checking that it works, which it does).
Context: The above, as I'm sure you realize, is 'almost' Laplace's equation. "If" a photon had mass (the term \mu would be proportional to it) the above equation would result for a region with no charge.
I'm guessing that the answer is simple so please be vague with your hints (I suppose that's almost asking for a smartass comment) as I'd like to figure it out myself.
Thanks
<br /> \frac{1}{r^2}\frac{\partial}{\partial r}r^2\frac{\partial \phi}{\partial r}+\mu^2 \phi=0<br />
I 'know' the solutions which are linear combinations of e^{\pm\mu r}/r as you can check, but I've been trying to see if I could show the fact (as opposed to just checking that it works, which it does).
Context: The above, as I'm sure you realize, is 'almost' Laplace's equation. "If" a photon had mass (the term \mu would be proportional to it) the above equation would result for a region with no charge.
I'm guessing that the answer is simple so please be vague with your hints (I suppose that's almost asking for a smartass comment) as I'd like to figure it out myself.
Thanks
