Compton Scattering off Relativistic Bound States: Two-Photon Vertices, Ward-Takahashi Identities, Gauge Invariance and Low-Energy Limit
Abstract
In a general framework that has been labeled the ``gauging of equations method'', we study the diagrams that contribute to Compton scattering off a relativistic composite system. These contributions can be derived for N--particle bound states described by the covariant Bethe--Salpeter equation with a method equivalent to minimal substitution in the one--particle case and yield the correct contributions (including subtraction terms) in the order O(e2). We give the Ward--Takahashi identities for the general two--photon vertex as well as the corresponding constraints for the two--photon irreducible interaction kernel and the Bethe--Salpeter amplitude describing the bound state. From this we can show that gauge invariance holds for the full two--photon vertex. We furthermore study in detail the low--energy limit of the Compton scattering tensor in this approach (including a discussion of the pole terms) and can prove that the full amplitude yields the correct Born--Thomson limit as we shall explicitly show for the spin--0 case. The calculations are completed by the investigation of certain approximations that can be formulated for arbitrary N--particle bound states. We neglect for instance contributions from n--photon irreducible interaction kernels and show that in this case gauge invariance is only realized if either the interaction kernel in the Bethe--Salpeter equation is independent of the total momentum and additionally is of local type, or if the photon energies vanish; furthermore, we find the correct low--energy limit in this approximation. To clarify our approach, we also give the results in the order O (e); as examples, we will quote some resulting lowest order expressions for a q q system explicitly.
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