Calculating Photon Frequency From Relativistic Decay: Homework Solution

Join the discussion
Ask a follow-up here, or get your own question answered by working scientists, mathematicians and engineers — people, not an autocomplete.
Real named experts · corrections over time · the nuance an AI answer skips
10 replies · 2K views
Physgeek64
Messages
245
Reaction score
11

Homework Statement


Hi- I've been doing some questions and came across the following

A high energy particle, traveling towards an observer with velocity v decays to produce a photon with
energy E in the rest frame of the particle.
Find the frequency at which this photon would be detected by the observer

Homework Equations

The Attempt at a Solution


so initially i tried:

conservation of energy in particles frame: mc^2=E
then transformed this into the lab frame
E'=gamma(E-vp)
E'=Esqrt((1-v/c)/1+v/c))

and then used E'=hc/lambda to get f=E/hcsqrt((1-v/c)/1+v/c))

but then here is my problem- surely the decay of a single particle into a single photon violates the conservation of momentum as in the particles frame it initially has momentum 0, but after the decay it has momentum E/c? I may be wrong, but I'm just slightly confused. Thanks :)
 
Physics news on Phys.org
PeroK said:
Are you sure the particle doesn't decay into two photons? By conservation of momentum a single particle cannot decay into a single particle with a different mass.
This is my problem... but that is the exact question
 
PeroK said:
It could decay into another unspecified particle and a photon. It doesn't say only a photon!
But surely the frequency of the photon would depend entirely on the mass of the other particle, so it would be odd not to mention it?
 
Physgeek64 said:
But surely the frequency of the photon would depend entirely on the mass of the other particle, so it would be odd not to mention it?

It gives you the energy of the photon. The mass of the original particle and the details of the decay are irrelevant.
 
PeroK said:
It gives you the energy of the photon. The mass of the original particle and the details of the decay are irrelevant.
ahh okay- so with the exception of my 'conservation of energy' line, my above answer should hold?
 
Physgeek64 said:
ahh okay- so with the exception of my 'conservation of energy' line, my above answer should hold?
conservation of energy in particles frame: mc^2=E
then transformed this into the lab frame
E'=gamma(E-vp)
E'=Esqrt((1-v/c)/1+v/c))and then used E'=hc/lambda to get f=E/hcsqrt((1-v/c)/1+v/c))

Are you sure that's right? What would Mr Doppler have to say?

Also, there's no need to introduce ##\lambda## as ##E' = hf_{obs}##
 
PeroK said:
Are you sure that's right? What would Mr Doppler have to say?

Also, there's no need to introduce ##\lambda## as ##E' = hf_{obs}##
I did initially think that, but the expression I've obtained is already that of the doppler shift? Or is that just a coincidence?

Oh yeah- silly me
 
Physgeek64 said:
I did initially think that, but the expression I've obtained is already that of the doppler shift? Or is that just a coincidence?

Oh yeah- silly me

It's no coincidence. The energy transformation for a photon leads to the relativistic Doppler formula. Is the energy/frequency of the observed photon (in your answer) greater than or less than the emitted photon? What should it be?
 
PeroK said:
It's no coincidence. The energy transformation for a photon leads to the relativistic Doppler formula. Is the energy/frequency of the observed photon (in your answer) greater than or less than the emitted photon? What should it be?
It should be greater, so the other way round. I've probably made an algebraic mistake somewhere. But thank you! that's really helpful :)