English

Integrand-Level Reduction of Loop Amplitudes by Computational Algebraic Geometry Methods

High Energy Physics - Phenomenology 2015-03-20 v3 High Energy Physics - Theory

Abstract

We present an algorithm for the integrand-level reduction of multi-loop amplitudes of renormalizable field theories, based on computational algebraic geometry. This algorithm uses (1) the Gr\"obner basis method to determine the basis for integrand-level reduction, (2) the primary decomposition of an ideal to classify all inequivalent solutions of unitarity cuts. The resulting basis and cut solutions can be used to reconstruct the integrand from unitarity cuts, via polynomial fitting techniques. The basis determination part of the algorithm has been implemented in the Mathematica package, BasisDet. The primary decomposition part can be readily carried out by algebraic geometry softwares, with the output of the package BasisDet. The algorithm works in both D=4 and D=42ϵD=4-2\epsilon dimensions, and we present some two and three-loop examples of applications of this algorithm.

Keywords

Cite

@article{arxiv.1205.5707,
  title  = {Integrand-Level Reduction of Loop Amplitudes by Computational Algebraic Geometry Methods},
  author = {Yang Zhang},
  journal= {arXiv preprint arXiv:1205.5707},
  year   = {2015}
}

Comments

published version: typos corrected; more examples added

R2 v1 2026-06-21T21:09:31.760Z