Visualizing How the Structure of Large-Radius Jets Shapes Their Wakes

Abstract

The ATLAS collaboration has introduced and implemented a strategy for selecting and analyzing large-radius jets composed of skinny R=0.2 subjets in heavy ion collisions at the LHC. We show how measurements of these jets teach us about the resolution length L res of quark-gluon plasma (QGP) and can teach us how jet substructure shapes the wakes that jets excite in the QGP droplets through which they pass. We use Hybrid Model calculations to reproduce measurements of RAA for large-radius jets in PbPb collisions, and study their dependence on the angle between the two skinny subjets involved in the final reclustering step of an R=1 jet. We show how these observables can constrain the value of L res and demonstrate that the ATLAS data rule out any picture in which an entire parton shower loses energy coherently as if it were a single entity. Determining the degree to which the QGP can resolve partons within a jet is central to the broader program of using jet quenching measurements to probe QGP. We make further use of this setup by analyzing the response of the medium to the passage of large-radius R=2 jets containing two skinny subjets in gamma-jet events. We introduce novel jet-shape observables that allow us to visualize the angular shape of the soft hadrons originating from the wakes that wide jets with two skinny subjets excite in a droplet of QGP, as a function of the angular separation between the subjets. We find that even when they are 0.8- 1 radian apart, a single broad wake is produced. Only when the two subjets are even farther apart is the presence of two sub-wakes revealed. We show that the way in which jet structure shapes jet wakes can be visualized with similar clarity in experiments by using only those hadrons with low pT. These observables thus offer a new and distinctive way of seeing jet wakes in heavy ion collision data.