Gain suppression study on LGADs at the CENPA tandem accelerator

TL;DR

This study investigates the gain suppression mechanism in LGADs caused by large localized charge deposits, using proton beam experiments to understand device response for high-energy physics applications.

Contribution

It provides experimental characterization of LGAD gain suppression under MeV proton irradiation, informing high-precision rare decay measurements.

Findings

Gain suppression depends on bias voltage, beam angle, and proton energy.

LGAD prototypes show measurable gain reduction with increased localized charge.

Results aid in optimizing LGAD performance for high-energy physics experiments.

Abstract

Low-Gain Avalanche Detectors (LGADs) are a type of thin silicon detector with a highly doped gain layer that provides moderate internal signal amplification. One recent challenge in the use of LGADs, studied by several research groups, is the gain suppression mechanism for large localized charge deposits. Using the CENPA Tandem accelerator at the University of Washington, the response of the LGADs to MeV-range energy deposits from a proton beam was studied. Two LGAD prototypes and a PIN diode were characterized, and the gain of the devices was determined as a function of bias voltage, incidence beam angle and proton energy. This study was conducted in the scope of the PIONEER experiment, an experiment proposed at the Paul Scherrer Institute to perform high-precision measurements of rare pion decays. %At the center of the experiment, a high-granularity active target (ATAR) will stop the pion and characterize its decay. A range of deposited charge from Minimum Ionizing Particle (MIP, few 10s of KeV) from positrons to several MeV from the stopping pions/muons is expected in PIONEER; the detection and separation of close-by hits in such a wide dynamic range will be a main challenge of the experiment. To achieve this goal, the gain suppression mechanism has to be understood fully.