Factorization and Resummation for Dijet Invariant Mass Spectra

TL;DR

This paper develops an effective field theory, SCET+,, to systematically resum large logarithms in dijet invariant mass spectra at colliders, improving precision in new-physics searches.

Contribution

It introduces SCET+,, an extension of soft-collinear effective theory, for accurate scale separation and resummation in hierarchical jet processes.

Findings

Constructed SCET+ for multiscale jet analysis

Resummed logarithms of m_jj/Q and m/Q systematically

Applied to e+e- and pp collider processes

Abstract

Multijet cross sections at the LHC and Tevatron are sensitive to several distinct kinematic energy scales. When measuring the dijet invariant mass m_jj between two signal jets produced in association with other jets or weak bosons, m_jj will typically be much smaller than the total partonic center-of-mass energy Q, but larger than the individual jet masses m, such that there can be a hierarchy of scales m << m_jj << Q. This situation arises in many new-physics analyses at the LHC, where the invariant mass between jets is used to gain access to the masses of new-physics particles in a decay chain. At present, the logarithms arising from such a hierarchy of kinematic scales can only be summed at the leading-logarithmic level provided by parton-shower programs. We construct an effective field theory, SCET+, which is an extension of soft-collinear effective theory that applies to this situation of hierarchical jets. It allows for a rigorous separation of different scales in a multiscale soft function and for a systematic resummation of logarithms of both m_jj/Q and m/Q. As an explicit example, we consider the invariant mass spectrum of the two closest jets in e+e- -> 3 jets. We also give the generalization to pp -> N jets plus leptons relevant for the LHC.