Next-to-leading power two-loop soft functions for the Drell-Yan process at threshold

Article
Report number	arXiv:2107.07353 ; IPPP/21/06 ; CERN-TH-2021-108
Title	Next-to-leading power two-loop soft functions for the Drell-Yan process at threshold
Author(s)	Broggio, Alessandro (Milan Bicocca U. ; INFN, Milan Bicocca) ; Jaskiewicz, Sebastian (Durham U., IPPP) ; Vernazza, Leonardo (CERN ; Turin U. ; INFN, Turin)
Publication	2021-10-07
Imprint	2021-07-15
Number of pages	33
In:	JHEP 2110 (2021) 061
DOI	10.1007/JHEP10(2021)061
Subject category	hep-ph ; Particle Physics - Phenomenology
Abstract	We calculate the generalized soft functions at $\mathcal{O}(\alpha_s^2)$ at next-to-leading power accuracy for the Drell-Yan process at threshold. The operator definitions of these objects contain explicit insertions of soft gauge and matter fields, giving rise to a dependence on additional convolution variables with respect to the leading power result. These soft functions constitute the last missing ingredient for the validation of the bare factorization theorem to NNLO accuracy. We carry out the calculations by reducing the soft squared amplitudes into a set of canonical master integrals and we employ the method of differential equations to evaluate them. We retain the exact $d$-dimensional dependence of the convolution variables at the integration boundaries in order to regulate the fixed-order convolution integrals. After combining our soft functions with the relevant collinear functions, we perform checks of the results at the cross-section level against the literature and expansion-by-regions calculations, at NNLO and partly at N$^3$LO, finding agreement.
Copyright/License	publication: © 2021-2024 The Authors (License: CC-BY-4.0), sponsored by SCOAP³ preprint: (License: arXiv nonexclusive-distrib 1.0)

$Diagrams contributing to the $S_1$ soft function. The part to the left (right) of the cut corresponds to the time-ordered (anti-time-ordered) part of the diagram, and lines labeled by $n_{\pm}$ with in (out)-going arrow correspond to soft Wilson lines $Y_{\mp}$($Y_{\mp}^{\dagger}$). The filled square in this figure stands for the soft covariant derivative and the Wilson lines contained in $\frac{i\partial_{\perp\mu}}{in_-\partial}\mathcal{B}_+^{\mu}=\frac{i\partial_{\perp\mu}}{in_-\partial} Y^{\dagger}_+[iD^{\mu}_{s}Y_+]$.$ $Diagrams contributing to the $S_1$ soft function. The part to the left (right) of the cut corresponds to the time-ordered (anti-time-ordered) part of the diagram, and lines labeled by $n_{\pm}$ with in (out)-going arrow correspond to soft Wilson lines $Y_{\mp}$($Y_{\mp}^{\dagger}$). The filled square in this figure stands for the soft covariant derivative and the Wilson lines contained in $\frac{i\partial_{\perp\mu}}{in_-\partial}\mathcal{B}_+^{\mu}=\frac{i\partial_{\perp\mu}}{in_-\partial} Y^{\dagger}_+[iD^{\mu}_{s}Y_+]$.$ $Diagrams contributing to the $S_1$ soft function. The part to the left (right) of the cut corresponds to the time-ordered (anti-time-ordered) part of the diagram, and lines labeled by $n_{\pm}$ with in (out)-going arrow correspond to soft Wilson lines $Y_{\mp}$($Y_{\mp}^{\dagger}$). The filled square in this figure stands for the soft covariant derivative and the Wilson lines contained in $\frac{i\partial_{\perp\mu}}{in_-\partial}\mathcal{B}_+^{\mu}=\frac{i\partial_{\perp\mu}}{in_-\partial} Y^{\dagger}_+[iD^{\mu}_{s}Y_+]$.$ Show more plots

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Record created 2021-07-16, last modified 2023-10-04

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