Evaluation of multiloop multiscale Feynman integrals for precision physics

Article
Report number	arXiv:2201.02576 ; CERN-TH-2021-230 ; UUITP-66/21
Title	Evaluation of multiloop multiscale Feynman integrals for precision physics
Related title	Evaluation of multi-loop multi-scale Feynman integrals for precision physics
Author(s)	Dubovyk, Ievgen (Silesia U.) ; Freitas, Ayres (Pittsburgh U.) ; Gluza, Janusz (Silesia U.) ; Grzanka, Krzysztof (Silesia U.) ; Hidding, Martijn (Uppsala U.) ; Usovitsch, Johann (CERN)
Publication	2022-12-01
Imprint	2022-01-07
Number of pages	7
In:	Phys. Rev. D 106 (2022) L111301
DOI	10.1103/PhysRevD.106.L111301 (publication)
Subject category	Particle Physics - Phenomenology
Abstract	Modern particle physics is increasingly becoming a precision science that relies on advanced theoretical predictions for the analysis and interpretation of experimental results. The planned physics program at the LHC and future colliders will require three-loop electroweak and mixed electroweak-QCD corrections to single-particle production and decay processes and two-loop electroweak corrections to pair production processes, all of which are beyond the reach of existing analytical and numerical techniques in their current form. This article presents a new semi-numerical approach based on differential equations with boundary terms specified at Euclidean kinematic points. These Euclidean boundary terms can be computed numerically with high accuracy using sector decomposition or other numerical methods. They are then mapped to the physical kinematic configuration with a series solution of the differential equation system. The method is able to deliver 8 or more digits precision, and it has a built-in mechanism for checking the accuracy of the obtained results. Its efficacy is illustrated with examples for three-loop self-energy and vertex integrals and two-loop box integrals.
Copyright/License	publication: © 2022-2024 authors (License: CC BY 4.0), sponsored by SCOAP³ preprint: (License: CC BY 4.0)

$Illustration of the DE transport method. The boundary conditions for the integral $f_i$ are evaluated at one or several Euclidean points $\rm A_k$, where the integral is purely real and one can obtain robustly converging numerical results with the SD method (using the package {\tt pySecDec} in our case). The boundary value(s) are transported to the physical kinematic point, using solutions of the DE system eq.~\eqref{eq:general-de} derived with {\tt DiffExp}, yielding the final result indicated by the red dot in the figure. The numerical uncertainty of a boundary value translates to an error estimate of the final result, as illustrated by the error bars in a zoomed-in area in the dotted circle, which permits a non-trivial cross-check if several boundary values $\rm A_k$ are employed.$ $Three loop self-energy non-planar and planar vertex diagrams which correspond to integrals in \eqref{eq:lhnp} and \eqref{eq:vtwPl}, respectively. W, Z and t stand for the W-boson, Z-boson and top quark, respectively.$ $Three loop self-energy non-planar and planar vertex diagrams which correspond to integrals in \eqref{eq:lhnp} and \eqref{eq:vtwPl}, respectively. W, Z and t stand for the W-boson, Z-boson and top quark, respectively.$ Show more plots

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Element opprettet 2022-01-12, sist endret 2023-10-04

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