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Main Authors: Horowitz, W. A., Plessis, J. F. Du
Format: Preprint
Published: 2023
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Online Access:https://arxiv.org/abs/2308.08651
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author Horowitz, W. A.
Plessis, J. F. Du
author_facet Horowitz, W. A.
Plessis, J. F. Du
contents We compute and explore numerically the finite system size correction to NLO $2\to2$ scattering in massive scalar $ϕ^4$ theory. The derivation uses "denominator regularization" (instead of the usual dimensional regularization) on a spacetime with spatial directions compactified to a torus, with characteristic lengths not necessarily of equal size. We determine a useful analytic continuation of the generalized Epstein zeta function to isolate the usual UV divergence. Self-consistently, the renormalized finite system size correction reduces to zero as the system size goes to infinity and, further, satisfies the optical theorem. One of our checks of unitarity leads to a generalization of a number theoretic result from Hardy and Ramanujan. Precise numerical exploration of the finite system size correction to the amplitude and coupling when two spatial dimensions are finite requires the exploitation of the analytic structure of the finite system size result via a dispersion relation. We find that the finite system size scattering amplitude exhibits "geometric" bound states. Even away from these bound states, the finite system size correction to the effective coupling can be large.
format Preprint
id arxiv_https___arxiv_org_abs_2308_08651
institution arXiv
publishDate 2023
record_format arxiv
spellingShingle Finite System Size Correction to the Effective Coupling in $ϕ^4$ Scattering
Horowitz, W. A.
Plessis, J. F. Du
High Energy Physics - Theory
High Energy Physics - Phenomenology
Nuclear Theory
We compute and explore numerically the finite system size correction to NLO $2\to2$ scattering in massive scalar $ϕ^4$ theory. The derivation uses "denominator regularization" (instead of the usual dimensional regularization) on a spacetime with spatial directions compactified to a torus, with characteristic lengths not necessarily of equal size. We determine a useful analytic continuation of the generalized Epstein zeta function to isolate the usual UV divergence. Self-consistently, the renormalized finite system size correction reduces to zero as the system size goes to infinity and, further, satisfies the optical theorem. One of our checks of unitarity leads to a generalization of a number theoretic result from Hardy and Ramanujan. Precise numerical exploration of the finite system size correction to the amplitude and coupling when two spatial dimensions are finite requires the exploitation of the analytic structure of the finite system size result via a dispersion relation. We find that the finite system size scattering amplitude exhibits "geometric" bound states. Even away from these bound states, the finite system size correction to the effective coupling can be large.
title Finite System Size Correction to the Effective Coupling in $ϕ^4$ Scattering
topic High Energy Physics - Theory
High Energy Physics - Phenomenology
Nuclear Theory
url https://arxiv.org/abs/2308.08651