What is the difference between the two 4-momenta in photon-electron collisions?

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The 4-momenta before a photon collides with a stationary election [itex]P_m=(mc^2,0,0,0)[/itex] or is it [itex]P_m=(mc,0,0,0)[/itex]

Which is the difference between the two?

Thanks.
 
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The four momentum is usually written in units of momentum, so (mc,0,0,0). However, it is even more common to use units where c=1, so that energy momentum and mass are all the same unit.
 
AishaGirl said:
Which is the difference between the two?
Units of energy versus units of momentum. I was trained in experimental particle physics, so I prefer units of energy ##(E, p_x c, p_y c, p_z c)## but I recognize that others prefer units of momentum ##(E/c, p_x, p_y, p_z)##. Whichever units you prefer, be consistent within a calculation!
 
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jtbell said:
I was trained in experimental particle physics, so I prefer units of energy
Interesting, does the particle physics community still call it the four momentum if they commonly use energy units?
 
Thanks for the replies. So using (mc,0,0,0) is just as valid as using (mc^2,0,0,0) ?
 
Sure, you only must be consistent with your convention or, most elegantly, set ##c=1##, as the particle physicists do (see the postings above). If I keep ##c \neq 1##, then I usually prefer to use the convention that the four-vector quantities have the dimension of the spatial parts, i.e., for momentum
$$(p^{\mu})=\begin{pmatrix} E/c \\ \vec{p} \end{pmatrix},$$
where ##E=c \sqrt{m^2 c^2+\vec{p}^2}## is the relativistic energy (i.e., kinetic + rest energy) of the particle. Then the energy-momentum relation (often called "on-shell condition") can be written in manifestly covariant form as
$$p_{\mu} p^{\mu}=m^2 c^2.$$

For the photon of momentum ##\vec{k}##, following thie convention you have
$$(k^{\mu}) = \begin{pmatrix} |\vec{k}|,\vec{k} \end{pmatrix}.$$
Because it's massless the energy of the photon is ##E_{\gamma}(\vec{k})=c |\vec{k}|##.
 
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