Performance of the ATLAS Muon Spectrometer and of Muon Identification at the LHC

Martin Woudstra

doi:10.22323/1.120.0029

Abstract

The large cosmic data samples collected in fall 2009 by the ATLAS experiment have been used to study the performance of the Muon Spectrometer. Detailed studies of the basic Muon spectrometer performance in terms of sagitta resolution, tracking efficiency and momentum resolution are presented and provide an update with respect to the results recently published. The results are also compared with a cosmic data simulation recently improved with a more realistic drift chamber response. The recent collision data collected at a CM of 7 TeV have also been analyzed to determine basic Muon Spectrometer performance. The performance of the ATLAS muon identification was studied with 1 inverse nanobarn of LHC proton-proton collision data at a centre of mass energy of 7 TeV. Measured detector efficiencies, hit multiplicities, and residual distributions of reconstructed muon tracks are well reproduced by the Monte Carlo simulation. Exploiting the redundancy in the muon identification at detector and reconstruction level the performance of the identification steps could be checked with data. 4.5 muons per microbarn with pT > 6 GeV and |?|<2.5 were identified as predicted by Pythia minimum bias Monte Carlo. The pseudorapidity, ?, and pT distributions of the reconstructed muons are in reasonable agreement with the Monte Carlo prediction.

Highlights

In the ATLAS detector [1], four kinds of muons are distinguished depending on the way they are reconstructed: Stand-alone muon: The muon trajectory is only reconstructed in the muon spectrometer, and is extrapolated to the beam line while correcting for the energy loss in the calorimeter.Combined muon: The measurement of the stand-alone muon is combined with the measurement in the inner detector.Segment tagged muon: A track in the inner detector is identified as a muon if its extrapolation to the muon spectrometer can be matched to (a) track segment(s) in the muon chambers.Calorimeter tagged muon: A track in the inner detector is identified as a muon if the associated energy deposition in the calorimeters is compatible with a minimum ionizing particle
The results on efficiency and resolution presented here use a sub-set of 21M events taken in fall 2009, where the magnetic field in the muon spectrometer is at nominal strength
The results presented here are updates to results published in [2], where details of these and other studies using the cosmics data can be found

Summary

Introduction

In the ATLAS detector [1], four kinds of muons are distinguished depending on the way they are reconstructed: Stand-alone muon: The muon trajectory is only reconstructed in the muon spectrometer, and is extrapolated to the beam line while correcting for the energy loss in the calorimeter. Combined muon: The measurement of the stand-alone muon is combined with the measurement in the inner detector. Segment tagged muon: A track in the inner detector is identified as a muon if its extrapolation to the muon spectrometer can be matched to (a) track segment(s) in the muon chambers. Calorimeter tagged muon: A track in the inner detector is identified as a muon if the associated energy deposition in the calorimeters is compatible with a minimum ionizing particle

Results from Cosmics

Muon Spectrometer Calibration and Alignment

Efficiency from Cosmics

Momentum resolution from Cosmics