Resonances: Universality and Factorization on Higher Sheets

TL;DR

This paper demonstrates that resonances, as poles on higher Riemann sheets of scattering amplitudes, exhibit universal properties like appearing in all S-matrix elements and factorizing on resonance poles, with their data encoded on the physical sheet.

Contribution

It establishes a nonperturbative framework showing resonances share properties with stable particles, applicable in any spacetime dimension and for complex Riemann surfaces.

Findings

Resonances appear in every S-matrix element.

Amplitudes factorize on resonance poles.

Resonance data are encoded on the physical sheet.

Abstract

Most particles in nature are unstable, manifesting as resonances in scattering processes. Using analyticity and unitarity, we show nonperturbatively that resonances, defined as poles on higher Riemann sheets of scattering amplitudes, share basic properties with stable particles: (i) Universality, that a resonance generically appears in every S-matrix element; and (ii) Factorization, that amplitudes factorize on resonance poles. Our framework applies in any spacetime dimension and across arbitrarily many two-particle cuts, including cases where the kinematic Riemann surface becomes infinitely sheeted. Importantly, we find that resonance data (mass, width, couplings, and sheet index) are fully encoded on the physical sheet, where causality can impose additional constraints. These results are relevant for extending S-matrix bootstrap studies beyond elastic scattering.