Spin and model identification of Z' bosons at the LHC

TL;DR

This paper investigates methods to determine the spin and distinguish between different Z' models at the LHC using angular distributions and cross sections of dilepton events, focusing on the feasibility up to several TeV in mass.

Contribution

It introduces a practical approach using the center-edge asymmetry to identify Z' spin and differentiate models at the LHC.

Findings

Spin of Z' can be established up to ~3.0 TeV with 100 fb^{-1}

Models can be distinguished at 95% C.L. up to ~2.1 TeV

Angular distributions are effective for spin determination.

Abstract

Heavy resonances appearing in the clean Drell-Yan channel may be the first new physics to be observed at the proton-proton CERN LHC. If a new resonance is discovered at the LHC as a peak in the dilepton invariant mass distribution, the characterization of its spin and couplings will proceed via measuring production rates and angular distributions of the decay products. We discuss the discrimination of the spin-1 of Z' representative models (Z'_{SSM}, Z'_{psi}, Z'_{eta}, Z'_{chi}, Z'_{LR}, and Z'_{ALR}) against the Randall-Sundrum graviton resonance (spin-2) and a spin-0 resonance (sneutrino) with the same mass and producing the same number of events under the observed peak. To assess the range of the Z' mass where the spin determination can be performed to a given confidence level, we focus on the angular distributions of the Drell-Yan leptons, in particular we use as a basic observable an angular-integrated center-edge asymmetry, A_{CE}. The spin of a heavy Z' gauge boson can be established with A_{CE} up to M_{Z'} \simeq 3.0 TeV, for an integrated luminosity of 100 fb^{-1}, or minimal number of events around 110. We also examine the distinguishability of the considered Z' models from one another, once the spin-1 has been established, using the total dilepton production cross section. With some assumption, one might be able to distinguish among these Z' models at 95% C.L. up to M_{Z'} \simeq 2.1 TeV.