Dijet production, collision centrality and backgrounds in high-energy p-p collisions

Abstract

Two aspects of high-energy collisions share common phenomenological elements: (a) A correlation between jet production and centrality is suggested by the transverse partonic structure of hadrons inferred from deep-inelastic scattering data. (b) The underlying event (UE) is defined as the final-state particles complementary to a triggered high-energy dijet. An observable common to both topics is variation of so-called transverse multiplicity N with a pt,trig dijet trigger. We test assumptions associated with collision centrality and the UE. We determine the nature of the UE and explore the relation between jet production and centrality. We use the two-component model (TCM) of spectra and correlations derived from 200 GeV collisions to construct a simulated particle distribution on (pt,nch) to predict the N response to pt,trig. The pt spectrum TCM combined in this analysis with measured minimum-bias angular correlations suggests that the UE includes a substantial contribution from the triggered dijet in addition to the contribution from projectile fragmentation (beam-beam remnants). The jet contribution to N may represent a universal large-angle base common to all dijets that extends across 2π azimuth. The analysis further suggests that centrality is not controlled significantly by pt,trig but may be correlated to some extent with an imposed nch condition, depending on the role of fluctuations. Future correlation studies may better determine the role of centrality. These results may have implications for ongoing RHIC analysis and LHC searches for physics beyond the standard model.