Difference between revisions of "Relativistic Differential Cross-section"
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− | <center><math>F=4\sqrt{(E_1^2+\vec p_1^2)^2-m^4}=4\sqrt{p_1^2+m^2+p_1^2-m^4}</math></center> | + | <center><math>F=4\sqrt{(E_1^2+\vec p_1^2)^2-m^4}=4\sqrt{(p_1^2+m^2+p_1^2)^2-m^4}</math></center> |
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+ | <center><math>F=4\sqrt{(2p_1^2+m^2)^2-m^4}=4\sqrt{4p_1^4+2m^4+4p_1^2m-m^4}</math></center> | ||
Revision as of 16:24, 4 July 2017
Relativistic Differential Cross-section
dQ is the invariant Lorentz phase space factor
and F is the flux of incoming particles
where is the relative velocity between the particles in the frame where particle 1 is at rest
Using the relativistic definition of energy
Letting be the energy of particle 2 wiith respect to particle 1, the relativistic energy equation can be rewritten such that
where similarly
is defined as the momentum of particle 2 with respect to particle 1.
The relative velocity can be expressed as
The invariant form of F is
where in the center of mass frame
In the center of mass frame