Determining the squark mass at the LHC

Abstract

We propose a new way to determine the squark mass based on the shape of di-jet invariant mass distribution of supersymmetry (SUSY) di-jet events at the Large Hadron Collider (LHC). Our algorithm, which is based on event kinematics, requires that the branching ratio B(q → q z1) is substantial for at least some types of squarks, and that mz12/mq2 1. We select di-jet events with no isolated leptons, and impose cuts on the total jet transverse energy, ETtot=ET(j1)+ET(j2), on α = ET(j2)/mjj, and on the azimuthal angle between the two jets to reduce SM backgrounds. The shape of the resulting di-jet mass distribution depends sensitively on the squark mass, especially if the integrated luminosity is sufficient to allow a hard enough cut on ETtot and yet leave a large enough signal to obtain the mjj distribution. We simulate the signal and Standard Model (SM) backgrounds for 100 fb-1 integrated luminosity at 14 TeV requiring ETtot> 700 GeV. We show that it should be possible to extract mq to within about 3% at 95% CL --- similar to the precision obtained using mT2 --- from the di-jet mass distribution if mq 650 GeV, or to within 5% if mq 1 TeV.