Predicting the performance of the CMS precision PbWO₄ electromagnetic calorimeter in the HL-LHC era from test beam results on irradiated crystals

The harsh radiation environment, in which detectors will have to operate during the high luminosity phase of the Large Hadron Collider, represents a crucial challenge for many calorimeter technologies. In the Compact Muon Solenoid (CMS) forward calorimeters, ionizing doses and hadron fluences will reach up to 300 kGy (at a dose rate of 30 Gy/h) and ${2\times 10^{14} cm^{-2}}$ , respectively, at the pseudorapidity region of $\vert \eta \vert $ = 2.6. To evaluate the evolution of the CMS electromagnetic calorimeter performance in such conditions, a set of PbWO₄ crystals, which had previously been exposed to 24 GeV protons up to integrated fluences between ${2.1\times 10^{13} cm^{-2}}$ and ${1.3\times 10^{14} cm^{-2}}$ , has been studied in beam tests. A degradation of the energy resolution and a nonlinear response to electron showers are observed in damaged crystals. Direct measurements of the light output from the crystals show the amplitude decreasing and pulse becoming faster as the fluence increases. The evolution of the performance of the PbWO₄ crystals has been well understood and parameterized in terms of increasing light absorption inside the crystal volume. A double-sided readout configuration, in which two identical photodetectors are coupled to the opposite ends of each crystal, has also been tested. The separate and simultaneous readout of the light from the two sides of the crystal allows us to correct for longitudinal shower fluctuations and to mitigate the degradation of energy resolution in highly damaged crystals. The nonlinear response to electromagnetic showers, arising from high nonuniformity of light collection efficiency along the longitudinal axis of irradiated crystals, can also be corrected by means of the double-sided readout technique.