# Point-Particle Catalysis

**Authors:** P. Hayman, C.P. Burgess

arXiv: 1905.00103 · 2019-05-02

## TL;DR

This paper employs the point-particle effective field theory framework to analyze particle conversion processes mediated by flavor-changing couplings at a point-particle, revealing renormalization requirements and momentum-dependent cross-section behaviors.

## Contribution

It introduces a novel application of PPEFT to flavor-changing particle interactions, detailing renormalization procedures and momentum effects, with implications for complex nuclear and particle physics reactions.

## Key findings

- Renormalization of point-particle couplings near the origin.
- Discovery of a 1/k_in enhancement in cross-sections.
- Connection to non-self-adjoint PPEFT and nuclear reactions.

## Abstract

We use the point-particle effective field theory (PPEFT) framework to describe particle-conversion mediated by a flavour-changing coupling to a point-particle. We do this for a toy model of two non-relativistic scalars coupled to the same point-particle, on which there is a flavour-violating coupling. It is found that the point-particle couplings all must be renormalized with respect to a radial cut-off near the origin, and it is an invariant of the flow of the flavour-changing coupling that is directly related to particle-changing cross-sections. At the same time, we find an interesting dependence of those cross-sections on the ratio k_out/k_in of the outgoing and incoming momenta, which can lead to a 1/k_in enhancement in certain regimes. We further connect this model to the case of a single-particle non-self-adjoint (absorptive) PPEFT, as well as to a PPEFT of a single particle coupled to a two-state nucleus. These results could be relevant for future calculations of any more complicated reactions, such as nucleus-induced electron-muon conversions, monopole catalysis of baryon number violation, as well as nuclear transfer reactions.

## Figures

4 figures with captions in the complete paper: https://tomesphere.com/paper/1905.00103/full.md

---
Source: https://tomesphere.com/paper/1905.00103