Design, development and performance study of six-gap glass MRPC detectors

TL;DR

This paper reports the design, fabrication, and performance evaluation of six-gap glass MRPC detectors optimized for timing and efficiency in TOF systems, demonstrating high efficiency and sub-nanosecond time resolution.

Contribution

It introduces a novel design with optimized spacers and gas mixture for six-gap glass MRPCs, enhancing performance for TOF applications.

Findings

Counting efficiency of about 95% at 17.9 kV

Time resolution of approximately 219 ps after correction

Optimized gas mixture improves detector performance

Abstract

The Multigap Resistive Plate Chambers (MRPCs) are gas ionization detectors with multiple gas sub-gaps made of resistive electrodes. The high voltage (HV) is applied on the outer surfaces of outermost resistive plates only, while the interior plates are left electrically floating. The presence of multiple narrow sub--gaps with high electric field results in faster signals on the outer electrodes, thus improving the detector's time resolution. Due to their excellent performance and relatively low cost, the MRPC detector has found potential application in Time-of-Flight (TOF) systems. Here we present the design, fabrication, optimization of the operating parameters such as the HV, the gas mixture composition, and, performance of six--gap glass MRPC detectors of area 27cm $\times$ 27 cm, which are developed in order to find application as trigger detectors, in TOF measurement etc. The design has been optimized with unique spacers and blockers to ensure a proper gas flow through the narrow sub-gaps, which are 250 $\mu$m wide. The gas mixture consisting of R134A, Isobutane and SF$_{6}$, and the fraction of each constituting gases has been optimized after studying the MRPC performance for a set of different concentrations. The counting efficiency of the MRPC is about 95% at $17.9$ kV. At the same operating voltage, the time resolution, after correcting for the walk effect, is found to be about $219$ ps.