Abstract

Many physics analyses using the Compact Muon Solenoid (CMS) detector at the LHC require accurate, high resolution electron and photon energy measurements. Particularly important are decays of the Higgs boson resulting in electromagnetic particles in the final state. Di-photon events in CMS are also a very important channel in the search for Higgs boson production in association with other particles or in the search for possible new resonances of higher mass. The requirement for high performance electromagnetic calorimetry therefore remains high during LHC Run II. Following the excellent performance achieved in Run~I at a center of mass energy of 7 and 8 TeV, the CMS electromagnetic calorimeter (ECAL) started operating at the LHC in Spring 2015 with proton-proton collisions at 13 TeV center-of-mass energy. The instantaneous luminosity delivered by the LHC during Run~II is expected to exceed the levels achieved in Run I, using 25 ns bunch spacing. The average number of concurrent proton-proton collisions per bunch-crossing (pileup) is expected to reach up to 40 interactions in 2016. These high pileup levels necessitate a retuning of the ECAL readout and trigger thresholds and reconstruction algorithms, to maintain the best possible performance in these more challenging conditions. The energy response of the detector must be precisely calibrated and monitored to achieve and maintain the excellent performance obtained in Run I in terms of energy scale and resolution. A dedicated calibration of each detector channel is performed with physics events exploiting electrons from W and Z boson decays, photons from $\pi^0$/$\eta$ decays and from the azimuthally symmetrical energy distribution of minimum bias events. This paper describes the new reconstruction algorithm and calibration strategies that we have implemented to maintain the excellent performance of the CMS ECAL throughout Run II. We will show performance results from the 2015 and 2016 data taking periods and provide an outlook on the expected Run II performance in the years to come.

Highlights

  • The Compact Muon Solenoid (CMS) electromagnetic calorimeter (ECAL) [1] is a hermetic, homogeneous detector consisting of 61,200 PbWO4 crystals in the barrel (EB), and 7324 crystals in each of the two endcap sections (EE)

  • A preshower (ES) detector made of lead absorbers and silicon strip sensors is placed in front of EE to improve the identification of closely spaced photons from π0 decays

  • In-situ ECAL calibrations with physics events had been performed in Run I to improve the energy resolution [3]

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Summary

Introduction

The CMS electromagnetic calorimeter (ECAL) [1] is a hermetic, homogeneous detector consisting of 61,200 PbWO4 crystals in the barrel (EB), and 7324 crystals in each of the two endcap sections (EE). A short radiation length (0.89 cm), small Molière radius (2.2 cm) and high radiation resistance make PbWO4 crystals the appropriate material for a compact calorimeter. A preshower (ES) detector made of lead absorbers and silicon strip sensors is placed in front of EE to improve the identification of closely spaced photons from π0 decays.

Energy reconstruction and calibration
Energy reconstruction
Energy calibration
ECAL Run II Performance
Conclusion

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