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Singularity-Free Feynman Integral Bases

High Energy Physics - Theory 2025-08-07 v1

Abstract

Standard integration-by-parts (IBP) reduction methods typically yield Feynman integral bases where the reduction of some integrals gives rise to coefficients singular as the dimensional regulator ϵ0\epsilon\rightarrow 0. These singular coefficients can also appear in scattering amplitudes, obscuring their structure, and rendering their evaluation more complicated. We investigate the use of bases in which the reduction of any integral is free of singular coefficients. We present two general algorithms for constructing such bases. The first is based on sequential D=4D=4 IBP reduction. It constructs a basis iteratively by projecting onto the finite part of the set of IBP relations. The second algorithm performs Gaussian elimination within a local ring forbidding division by ϵ\epsilon while permitting division by polynomials in ϵ\epsilon finite at ϵ=0\epsilon=0. We study the application of both algorithms to a pair of two-loop examples, the planar and nonplanar double-box families of integrals. We also explore the incorporation of finite Feynman integrals into these bases. In one example, the resulting basis provides a simpler and more compact representation of a scattering amplitude.

Keywords

Cite

@article{arxiv.2508.04394,
  title  = {Singularity-Free Feynman Integral Bases},
  author = {Stefano De Angelis and David A. Kosower and Rourou Ma and Zihao Wu and Yang Zhang},
  journal= {arXiv preprint arXiv:2508.04394},
  year   = {2025}
}

Comments

18 pages

R2 v1 2026-07-01T04:37:16.627Z