21joanna12
- 126
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I am trying to derive the gravitational red shift effect but I think I am going about it all wrong. Specifically, I want to derive the change in frequency/ wavelength when a photon moves away from the surface of a star mass M and radius R.
So I tried to use relativistic mass of the photon and I got something along the lines of:
\Delta E= h\Delta f = GMm_{rel}\left(\frac{1}{R}-\frac{1}{r}\right)
And then substituting in m_{rel}=\frac{hf}{c^2}
Would give \Delta f =\frac{GMf}{c^2}\left(\frac{1}{R}-\frac{1}{r}\right)
But then I realized that f would be changing as the photon leaves the surface, so I thought that maybe I have to integrate?
Considering the photon rising a small distance \delta r and rearranging would give
\int\frac{1}{f} df =\frac{GM}{c^2}\int\frac{dr}{r(r+dr)}
So it is a big mess right now! Would appreciate if someone could tell me where I am going wrong...
So I tried to use relativistic mass of the photon and I got something along the lines of:
\Delta E= h\Delta f = GMm_{rel}\left(\frac{1}{R}-\frac{1}{r}\right)
And then substituting in m_{rel}=\frac{hf}{c^2}
Would give \Delta f =\frac{GMf}{c^2}\left(\frac{1}{R}-\frac{1}{r}\right)
But then I realized that f would be changing as the photon leaves the surface, so I thought that maybe I have to integrate?
Considering the photon rising a small distance \delta r and rearranging would give
\int\frac{1}{f} df =\frac{GM}{c^2}\int\frac{dr}{r(r+dr)}
So it is a big mess right now! Would appreciate if someone could tell me where I am going wrong...