Precision timing detectors

TL;DR

This review discusses recent advancements in precision timing detectors crucial for high-energy physics experiments, focusing on technologies like scintillators, SiPMs, LGADs, and MRPCs, and their integration into collider systems.

Contribution

It provides a comprehensive survey of recent detector technologies, their physical principles, and future directions in precision timing for collider experiments.

Findings

Significant progress in timing measurement technologies for collider environments.

Integration examples from current collider experiments.

Emerging technologies with potential impact on future experiments.

Abstract

Precision timing has played a critical role in high-energy physics experiments, particularly for particle identification and the suppression of pileup under the challenging conditions expected at future colliders like the High-Luminosity Large Hadron Collider (HL-LHC). Over the past decades, significant advancements in timing measurement technologies have been made to meet the demands of increasingly complex collider environments. After introducing the motivation for precision timing in collider experiments, the underlying physical principles of timing measurements and the most important factors influencing the time resolution of a detector, this review presents a survey of key detector technologies developed in recent years, including scintillators read out by silicon photo-multipliers (SiPMs), low-gain avalanche diodes (LGADs), multi-gap resistive plate chambers (MRPCs). The integration of precision timing into large-scale systems is discussed with examples from detectors at current collider experiments. Finally, we explore emerging technologies and future directions in the field, highlighting their potential impact on the next generation of high-energy physics experiments.