Elastic lepton-proton two-photon exchange scattering: An exact HB$\chi$PT analysis including hadronic effects at NNLO

TL;DR

This paper provides an exact analytical calculation of two-photon exchange corrections in low-energy elastic lepton-proton scattering using heavy-baryon chiral perturbation theory, including hadronic effects at NNLO.

Contribution

It offers the first exact analytical evaluation of TPE corrections at NNLO in HBχPT, including hadronic effects and proton structure contributions.

Findings

Residual proton structure effects are present at order α/M².

Next-to-next-to-leading order corrections are small, indicating good convergence.

Analytical results show non-vanishing TPE effects despite cancellations.

Abstract

We present an exact analytical evaluation of the two-photon exchange (TPE) correction to the elastic lepton-proton differential scattering cross section at low-energies within the framework of heavy-baryon chiral perturbation theory. Our analysis focuses on the kinematic regime relevant to the ongoing MUSE experiment, and we therefore restrict the intermediate states to the dominant elastic channel. All loop integrals are evaluated analytically without approximations. Radiative and chiral recoil contributions of the proton are included, retaining kinematical and dynamical TPE corrections to the cross section through next-to-next-to-leading order [i.e., ${\mathcal O}(\alpha/M^2)$] accuracy in the recoil expansion where $M$ is the proton mass. At this chiral order, pion-loop contributions demonstrate that structure-dependent TPE effects arise through the proton form factors. Our analytical results for the scattering cross section reveal non-vanishing residual proton structure effects of ${\mathcal O}(\alpha/M^2)$, despite substantial cancellations between TPE box and crossed-box contributions. Such effects were entirely absent at this accuracy in our earlier analysis based on the soft-photon approximation. Although the next-to-leading-order contributions are numerically sizable, the next-to-next-to-leading-order TPE corrections are found to be small, thereby indicating that the chiral expansion exhibits reasonably good perturbative convergence.