The Edge of Jets and Subleading Non-Global Logs

TL;DR

This paper develops a systematic soft jet expansion framework to calculate and resum non-global logarithms in jet physics, improving the understanding of jet correlations and subleading effects at high-energy colliders.

Contribution

It introduces a new effective field theory approach for soft jets, providing a factorization theorem and collinear improvements for non-global logarithm resummation.

Findings

Resummed subleading non-global logs in hemisphere jet mass distribution.

Developed a collinear improvement of the BMS equation.

Reduced need for kinematic-dependent IR corrections.

Abstract

A persistent and fascinating problem at the high energy colliders are jets. Often trying to observe physics underlying the hard interactions at colliders requires experimental cuts in phase space, defining several jet or beam regions. QCD being a gauge theory that readily decays into infra-red modes, correlations between jet regions is almost inevitable, spoiling the predictivity of fixed order QCD calculations. One is faced with the task of calculating the evolution of a reduced density matrix, where successively less energetic (jet) regions are integrated out, to gain control of the calculation. I relate the decay rates governing the flow into the IR to an effective field theory expansion in soft jets, allowing a systematic and resummed calculation of these rates, while further relating them to physically observable features of the QCD cascade. To demonstrate the utility of the soft jet expansion, I present a factorization theorem for a soft subjet collinearly splitting in and out of a parent fat jet. Using the resummation properties of this factorization theorem, I elucidate the structure of the subleading non-global logs (encoding the jet correlations) in the hemisphere jet mass distribution, as well as give a collinear improvement of the leading order resummation equation, the BMS equation. I compare to other approaches to subleading resummation of NGLs, and find the collinear improvement of the leading order equation removes the need for kinematic-dependent corrections in the IR averaging procedure of the reduced density matrix, so that no further large logs can be generated in the IR. Finally I end with speculation about connections with collinear improvements of the NLO B-JIMWLK hierarchy for small-$x$ resummation.