High energy scattering in perturbative quantum gravity at next-to-leading power

We consider the relativistic scattering of unequal-mass scalar particles through graviton exchange in the small-angle high-energy regime. We show the self-consistency of expansion around the eikonal limit and compute the scattering amplitude up to the next-to-leading power correction of the light particle energy, including gravitational effects of the same order. The first power correction is suppressed by a single power of the ratio of momentum transfer to the energy of the light particle in the rest frame of the heavy particle, independent of the heavy particle mass. We find that only gravitational corrections contribute to the exponentiated phase in impact parameter space in four dimensions. For large enough heavy-particle mass, the saddle point for the impact parameter is modified compared to the leading order by a multiple of the Schwarzschild radius determined by the mass of the heavy particle, independent of the energy of the light particle.

Automated summary

This study focuses on the relativistic scattering of unequal-mass scalar particles through graviton exchange in the small-angle high-energy regime. The self-consistency of the expansion around the eikonal limit is demonstrated, and the scattering amplitude is computed up to the next-to-leading power correction, including gravitational effects of the same order. Furthermore, it is found that only gravitational corrections contribute to the exponentiated phase in impact parameter space in four dimensions.