Skip to main content
Article

New NLOPS predictions for $$\varvec{t \bar{t} +b}$$ t t ¯ + b -jet production at the LHC

Tomáš JežoPhysics Institute, Universität Zürich, Zurich, SwitzerlandJonas M. LindertInstitute for Particle Physics Phenomenology, Durham University, South Rd, Durham, DH1 3LE, UKN. MorettiPhysics Institute, Universität Zürich, Zurich, SwitzerlandStefano PozzoriniPhysics Institute, Universität Zürich, Zurich, Switzerland
2018en
ABI

Abstract

Measurements of $$t \bar{t} H$$ production in the $$H\rightarrow b \bar{b} $$ channel depend in a critical way on the theoretical uncertainty associated with the irreducible $$t \bar{t} +b$$ -jet background. In this paper, analysing the various topologies that account for b-jet production in association with a $$t \bar{t} $$ pair, we demonstrate that the process at hand is largely driven by final-state $$g\rightarrow b \bar{b} $$ splittings. We also show that in five-flavour simulations based on $$t \bar{t} +$$ multi-jet merging, b-jet production is mostly driven by the parton shower, while matrix elements play only a marginal role in the description of $$g\rightarrow b \bar{b} $$ splittings. Based on these observations we advocate the use of NLOPS simulations of $$pp\rightarrow t \bar{t} b\bar{b} $$ in the four-flavour scheme, and we present a new Powheg generator of this kind. Predictions and uncertainties for $$t \bar{t} +b$$ -jet observables at the 13 TeV LHC are presented both for the case of stable top quarks and with spin-correlated top decays. Besides QCD scale variations we consider also theoretical uncertainties related to the Powheg matching method and to the parton shower modelling, with emphasis on $$g\rightarrow b \bar{b} $$ splittings. In general, matching and shower uncertainties turn out to be remarkably small. This is confirmed also by a consistent comparison against Sherpa+OpenLoops.

Identifiers

Citations and references

Cited by 30 references