English

Classical Spin Transitions and Absorptive Scattering

High Energy Physics - Theory 2026-01-05 v2

Abstract

We describe an on-shell, amplitudes-based approach to incorporating radiation absorption effects in the post-Minkowskian scattering of generic, compact, spinning bodies. Classical spinning observables are recovered by extrapolating to large spin, results calculated with finite quantum spin-ss particles using the properties of spin universality and Casimir interpolation. At leading-order our results give a completely general and non-redundant parametrization of absorptive observables in terms of a finite number of Wilson coefficients associated with 3-particle mass and spin-magnitude changing on-shell amplitudes. We denote these semi-fictitious microscopic processes: \textit{classical spin transitions}. Explicit results for the leading-order impulse due to the absorption of scalar, electromagnetic and gravitational radiation, for spin transitions Δs=0,±1,±2\Delta s = 0,\pm 1, \pm 2 are given in a fully interpolated form up to O(S2)\mathcal{O}\left(S^2\right), and Casimir independent contributions given up to O(S4)\mathcal{O}\left(S^4\right). Our explicit results reveal some surprising universal patterns. We find that, up to identification of Wilson coefficients, the Casimir independent contributions to the impulse for spinning-up and spinning-down by the same magnitude Δs|\Delta s| are identical. For processes where the quantum Δs<0\Delta s<0 transition is forbidden, the corresponding classical observable is suppressed in powers of SS by a predictable amount. Additionally we find that, while for generic non-aligned spin configurations there is a non-zero scattering angle at leading-order, for aligned spin, similar to non-spinning absorption, the scattering angle vanishes and the impulse is purely longitudinal.

Keywords

Cite

@article{arxiv.2511.19601,
  title  = {Classical Spin Transitions and Absorptive Scattering},
  author = {Juan Pablo Gatica and Callum R. T. Jones},
  journal= {arXiv preprint arXiv:2511.19601},
  year   = {2026}
}

Comments

40 pages, 5 figures

R2 v1 2026-07-01T07:53:00.888Z