Crossing (physics)

General overview

Consider an amplitude M ( ϕ ( p ) + . . .   → . . . ) . We concentrate our attention on one of the incoming particles with momentum p. The quantum field ϕ ( p ) , corresponding to the particle is allowed to be either bosonic or fermionic. Crossing symmetry states that we can relate the amplitude of this process to the amplitude of a similar process with an outgoing antiparticle ϕ ¯ ( − p ) replacing the incoming particle ϕ ( p ) : M ( ϕ ( p ) + . . . → . . . ) = M ( . . . → . . . + ϕ ¯ ( − p ) ) .

In the bosonic case, the idea behind crossing symmetry can be understood intuitively using Feynman diagrams. Consider any process involving an incoming particle with momentum p. For the particle to give a measurable contribution to the amplitude, it has to interact with a number of different particles with momenta k 1 , k 2 , . . . , k n via a vertex. Conservation of momentum implies ∑ k = 1 n q k = p . In case of an outgoing particle, conservation of momentum reads as ∑ k = 1 n q k = − p . Thus, replacing an incoming boson with an outgoing antiboson with opposite momentum yields the same S-matrix element.

In fermionic case, one can apply the same argument but now the relative phase convention for the external spinors must be taken into account.

Example

For example, the annihilation of an electron with a positron into two photons is related to an elastic scattering of an electron with a photon (Compton scattering) by crossing symmetry. This relation allows to calculate the scattering amplitude of one process from the amplitude for the other process if negative values of energy of some particles are substituted.