Role of IR-Improvement in Precision LHC/FCC Physics and in Quantum   Gravity

B.F.L. Ward (1); S. Jadach (2); W. Placzek (3); M. Skrzypek (2); Z. A.; Was (2); S. A. Yost (4) ((1) Baylor University; Waco; TX; USA; (2) Institute; of Nuclear Physics; Krakow; PL; (3) Jagiellonian University; Krakow; PL; (4); The Citadel; Charleston; SC; USA)

arXiv:2002.01850·hep-ph·August 17, 2021·1 cites

Role of IR-Improvement in Precision LHC/FCC Physics and in Quantum Gravity

B.F.L. Ward (1), S. Jadach (2), W. Placzek (3), M. Skrzypek (2), Z. A., Was (2), S. A. Yost (4) ((1) Baylor University, Waco, TX, USA, (2) Institute, of Nuclear Physics, Krakow, PL, (3) Jagiellonian University, Krakow, PL, (4), The Citadel, Charleston, SC, USA)

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TL;DR

This paper discusses how IR-improvement via amplitude-level resummation enhances precision in LHC/FCC physics and quantum gravity by controlling unintegrable results.

Contribution

It introduces IR-improvement based on amplitude-level resummation as a method to improve theoretical precision in high-energy physics and quantum gravity.

Findings

01

Resummation controls unintegrable results in quantum field theory.

02

Application to LHC and FCC physics improves prediction accuracy.

03

Illustrates potential in quantum gravity calculations.

Abstract

IR-improvement based on amplitude-level resummation allows one to control unintegrable results in quantum field theory with arbitrary precision in principle. We illustrate such resummation in specific examples in precision LHC and FCC physics and in quantum gravity.

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Taxonomy

TopicsParticle physics theoretical and experimental studies · Black Holes and Theoretical Physics · Noncommutative and Quantum Gravity Theories