Sub-10 ps time tagging of electromagnetic showers with scintillating glasses and SiPMs

TL;DR

This paper demonstrates sub-10 ps time resolution in electromagnetic shower detection using cerium-doped scintillating glasses read out with SiPMs, advancing detector timing capabilities for future collider experiments.

Contribution

It presents a novel application of cerium-doped alkali-free fluorophosphate glasses with SiPMs achieving unprecedented timing resolution for electromagnetic showers.

Findings

Single sensor time resolution of 14.4 ps for charged tracks.

Time resolution of 5-7 ps for shower development.

Potential for improved time-of-flight measurements in collider detectors.

Abstract

The high energy physics community has recently identified an $e^+e^-$ Higgs factory as one of the next-generation collider experiments, following the completion of the High Luminosity LHC program at CERN.The moderate radiation levels expected at such colliders compared to hadron colliders, enable the use of less radiation tolerant but cheaper technologies for the construction of the particle detectors. This opportunity has triggered a renewed interest in the development of scintillating glasses for the instrumentation of large detector volumes such as homogeneous calorimeters. While the performance of such scintillators remains typically inferior in terms of light yield and radiation tolerance compared to that of many scintillating crystals, substantial progress has been made over the recent years. In this paper we discuss the time resolution of cerium-doped Alkali Free Fluorophosphate scintillating glasses, read-out with silicon photo-multipliers in detecting single charged tracks and at different positions along the longitudinal development of an electromagnetic shower, using respectively 150~GeV pions and 100~GeV electron beams at the CERN SPS H2 beam line. A single sensor time resolution of 14.4~ps and 5-7~ps was measured respectively in the two cases. With such a performance the present technology has the potential to address an emerging requirement of future detectors at collider experiments: measuring the time-of-flight of single charged particles as well as that of neutral particles showering inside the calorimeter and the time development of showers.