We consider the class of inclusive hadron collider processes in which several energetic jets are produced, possibly accompanied by colorless particles [such as Higgs boson(s), vector boson(s) with their leptonic decays, and so forth]. We propose a new variable that smoothly captures the N+1 to N-jet transition. This variable, that we dub kTness, represents an effective transverse momentum controlling the singularities of the N+1-jet cross section when the additional jet is unresolved. The kTness variable offers novel opportunities to perform higher-order calculations in quantum chromodynamics by using nonlocal subtraction schemes. We study the singular behavior of the N+1-jet cross section as kTness→0 and, as a phenomenological application, we use the ensuing results to evaluate next-to-leading-order corrections to H+jet and Z+2-jet production at the LHC. We show that kTness performs extremely well as a resolution variable and appears to be very stable with respect to hadronization and multiple-parton interactions.
Buonocore, L., Grazzini, M., Haag, J., Rottoli, L., Savoini, C. (2022). Effective transverse momentum in multiple jet production at hadron colliders. PHYSICAL REVIEW D, 106(1) [10.1103/PhysRevD.106.014008].
Effective transverse momentum in multiple jet production at hadron colliders
Rottoli L.;
2022
Abstract
We consider the class of inclusive hadron collider processes in which several energetic jets are produced, possibly accompanied by colorless particles [such as Higgs boson(s), vector boson(s) with their leptonic decays, and so forth]. We propose a new variable that smoothly captures the N+1 to N-jet transition. This variable, that we dub kTness, represents an effective transverse momentum controlling the singularities of the N+1-jet cross section when the additional jet is unresolved. The kTness variable offers novel opportunities to perform higher-order calculations in quantum chromodynamics by using nonlocal subtraction schemes. We study the singular behavior of the N+1-jet cross section as kTness→0 and, as a phenomenological application, we use the ensuing results to evaluate next-to-leading-order corrections to H+jet and Z+2-jet production at the LHC. We show that kTness performs extremely well as a resolution variable and appears to be very stable with respect to hadronization and multiple-parton interactions.
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