Functions Beyond Multiple Polylogarithms for Precision Collider Physics

Research output: Working paperPreprintResearch

Standard

Functions Beyond Multiple Polylogarithms for Precision Collider Physics. / Bourjaily, Jacob L.; Broedel, Johannes; Chaubey, Ekta; Duhr, Claude; Frellesvig, Hjalte; Hidding, Martijn; Marzucca, Robin; McLeod, Andrew J.; Spradlin, Marcus; Tancredi, Lorenzo; Vergu, Cristian; Volk, Matthias; Volovich, Anastasia; Hippel, Matt von; Weinzierl, Stefan; Wilhelm, Matthias; Zhang, Chi.

2022.

Research output: Working paperPreprintResearch

Harvard

Bourjaily, JL, Broedel, J, Chaubey, E, Duhr, C, Frellesvig, H, Hidding, M, Marzucca, R, McLeod, AJ, Spradlin, M, Tancredi, L, Vergu, C, Volk, M, Volovich, A, Hippel, MV, Weinzierl, S, Wilhelm, M & Zhang, C 2022 'Functions Beyond Multiple Polylogarithms for Precision Collider Physics'. <https://arxiv.org/pdf/2203.07088.pdf>

APA

Bourjaily, J. L., Broedel, J., Chaubey, E., Duhr, C., Frellesvig, H., Hidding, M., Marzucca, R., McLeod, A. J., Spradlin, M., Tancredi, L., Vergu, C., Volk, M., Volovich, A., Hippel, M. V., Weinzierl, S., Wilhelm, M., & Zhang, C. (Accepted/In press). Functions Beyond Multiple Polylogarithms for Precision Collider Physics. https://arxiv.org/pdf/2203.07088.pdf

Vancouver

Bourjaily JL, Broedel J, Chaubey E, Duhr C, Frellesvig H, Hidding M et al. Functions Beyond Multiple Polylogarithms for Precision Collider Physics. 2022 Mar 14.

Author

Bourjaily, Jacob L. ; Broedel, Johannes ; Chaubey, Ekta ; Duhr, Claude ; Frellesvig, Hjalte ; Hidding, Martijn ; Marzucca, Robin ; McLeod, Andrew J. ; Spradlin, Marcus ; Tancredi, Lorenzo ; Vergu, Cristian ; Volk, Matthias ; Volovich, Anastasia ; Hippel, Matt von ; Weinzierl, Stefan ; Wilhelm, Matthias ; Zhang, Chi. / Functions Beyond Multiple Polylogarithms for Precision Collider Physics. 2022.

Bibtex

@techreport{dc1e331aa1ee4e85beea906225b8c917,
title = "Functions Beyond Multiple Polylogarithms for Precision Collider Physics",
abstract = " Feynman diagrams constitute one of the essential ingredients for making precision predictions for collider experiments. Yet, while the simplest Feynman diagrams can be evaluated in terms of multiple polylogarithms -- whose properties as special functions are well understood -- more complex diagrams often involve integrals over complicated algebraic manifolds. Such diagrams already contribute at NNLO to the self-energy of the electron, $t \bar{t}$ production, $\gamma \gamma$ production, and Higgs decay, and appear at two loops in the planar limit of maximally supersymmetric Yang-Mills theory. This makes the study of these more complicated types of integrals of phenomenological as well as conceptual importance. In this white paper contribution to the Snowmass community planning exercise, we provide an overview of the state of research on Feynman diagrams that involve special functions beyond multiple polylogarithms, and highlight a number of research directions that constitute essential avenues for future investigation. ",
keywords = "hep-ph, hep-th",
author = "Bourjaily, {Jacob L.} and Johannes Broedel and Ekta Chaubey and Claude Duhr and Hjalte Frellesvig and Martijn Hidding and Robin Marzucca and McLeod, {Andrew J.} and Marcus Spradlin and Lorenzo Tancredi and Cristian Vergu and Matthias Volk and Anastasia Volovich and Hippel, {Matt von} and Stefan Weinzierl and Matthias Wilhelm and Chi Zhang",
note = "32+24 pages, 11 figures, contribution to Snowmass 2021",
year = "2022",
month = mar,
day = "14",
language = "English",
type = "WorkingPaper",

}

RIS

TY - UNPB

T1 - Functions Beyond Multiple Polylogarithms for Precision Collider Physics

AU - Bourjaily, Jacob L.

AU - Broedel, Johannes

AU - Chaubey, Ekta

AU - Duhr, Claude

AU - Frellesvig, Hjalte

AU - Hidding, Martijn

AU - Marzucca, Robin

AU - McLeod, Andrew J.

AU - Spradlin, Marcus

AU - Tancredi, Lorenzo

AU - Vergu, Cristian

AU - Volk, Matthias

AU - Volovich, Anastasia

AU - Hippel, Matt von

AU - Weinzierl, Stefan

AU - Wilhelm, Matthias

AU - Zhang, Chi

N1 - 32+24 pages, 11 figures, contribution to Snowmass 2021

PY - 2022/3/14

Y1 - 2022/3/14

N2 - Feynman diagrams constitute one of the essential ingredients for making precision predictions for collider experiments. Yet, while the simplest Feynman diagrams can be evaluated in terms of multiple polylogarithms -- whose properties as special functions are well understood -- more complex diagrams often involve integrals over complicated algebraic manifolds. Such diagrams already contribute at NNLO to the self-energy of the electron, $t \bar{t}$ production, $\gamma \gamma$ production, and Higgs decay, and appear at two loops in the planar limit of maximally supersymmetric Yang-Mills theory. This makes the study of these more complicated types of integrals of phenomenological as well as conceptual importance. In this white paper contribution to the Snowmass community planning exercise, we provide an overview of the state of research on Feynman diagrams that involve special functions beyond multiple polylogarithms, and highlight a number of research directions that constitute essential avenues for future investigation.

AB - Feynman diagrams constitute one of the essential ingredients for making precision predictions for collider experiments. Yet, while the simplest Feynman diagrams can be evaluated in terms of multiple polylogarithms -- whose properties as special functions are well understood -- more complex diagrams often involve integrals over complicated algebraic manifolds. Such diagrams already contribute at NNLO to the self-energy of the electron, $t \bar{t}$ production, $\gamma \gamma$ production, and Higgs decay, and appear at two loops in the planar limit of maximally supersymmetric Yang-Mills theory. This makes the study of these more complicated types of integrals of phenomenological as well as conceptual importance. In this white paper contribution to the Snowmass community planning exercise, we provide an overview of the state of research on Feynman diagrams that involve special functions beyond multiple polylogarithms, and highlight a number of research directions that constitute essential avenues for future investigation.

KW - hep-ph

KW - hep-th

M3 - Preprint

BT - Functions Beyond Multiple Polylogarithms for Precision Collider Physics

ER -

ID: 300678131