Particle theory

Mixed QCD-electroweak corrections to W-boson production in hadron collisions

(2020)

Authors:

Arnd Behring, Federico Buccioni, Fabrizio Caola, Maximillian Delto, Matthieu Jaquier, Kirill Melnikov, Raoul Röntsch

Topological Gravity as the Early Phase of Our Universe

(2020)

Authors:

Prateek Agrawal, Sergei Gukov, Georges Obied, Cumrun Vafa

Elements of QCD for hadron colliders

CERN Yellow Reports: School Proceedings 5:2018 (2020) 1-56

Abstract:

The aim of these lectures is to provide students with an introduction to some of the core concepts and methods of QCD that are relevant in an LHC context.Â

Exploring Hamiltonian truncation in d=2+1

Physical Review D American Physical Society (APS) 102:6 (2020) 065001

Authors:

Joan Elias-Miró, Edward Hardy

On the impact of non-factorisable corrections in VBF single and double Higgs production

Journal of High Energy Physics Springer 2020:10 (2020) 131

Authors:

Fa Dreyer, A Karlberg, L Tancredi

Abstract:

We study the non-factorisable QCD corrections, computed in the eikonal approximation, to Vector-Boson Fusion single and double Higgs production and show the combined factorisable and non-factorisable corrections for both processes at O(αs2). We investigate the validity of the eikonal approximation with and without selection cuts, and carry out an in-depth study of the relative size of the non-factorisable next-to-next-to-leading order corrections compared to the factorisable ones. In the case of single Higgs production, after selection cuts are applied, the non-factorisable corrections are found to be mostly contained within the factorisable scale uncertainty bands. When no cuts are applied, instead, the non-factorisable corrections are slightly outside the scale uncertainty band. Interestingly, for double Higgs production, we find that both before and after applying cuts, non-factorisable corrections are enhanced compared to the single Higgs case. We trace this enhancement to the existence of delicate cancellations between the various leading-order Feynman diagrams, which are partly spoiled by radiative corrections. All contributions studied here have been implemented in proVBFH v1.2.0 and proVBFHH v1.1.0.