Modeling a Thick Hydrogenated Amorphous Silicon Substrate for Ionizing Radiation Detectors

Authors

Jeremy A. Davis, University Of WollongongFollow
Maurizio Boscardin
Michele Crivellari
Livio Fano
Matthew Large, University of WollongongFollow
Mauro Menichelli
Arianna Morozzi
Francesco Moscatelli
Maria Movileanu-Ionica
Daniele Passeri
Marco Petasecca, University of WollongongFollow
Mauro Piccini
Alessandro Rossi
Andrea Scorzoni
Bailey Thompson, University of Wollongong
Giovanni Verzellesi
Nicolas Wyrsch

RIS ID

143385

Publication Details

Davis, J., Boscardin, M., Crivellari, M., Fano, L., Large, M., Menichelli, M., Morozzi, A., Moscatelli, F., Movileanu-Ionica, M., Passeri, D., Petasecca, M., Piccini, M., Rossi, A., Scorzoni, A., Thompson, B., Verzellesi, G. & Wyrsch, N. (2020). Modeling a Thick Hydrogenated Amorphous Silicon Substrate for Ionizing Radiation Detectors. Frontiers in Physics, 8 158-1-158-10.

Abstract

© Copyright © 2020 Davis, Boscardin, Crivellari, Fanò, Large, Menichelli, Morozzi, Moscatelli, Movileanu-Ionica, Passeri, Petasecca, Piccini, Rossi, Scorzoni, Thompson, Verzellesi and Wyrsch. There is currently a renewed interest in hydrogenated amorphous silicon (a-Si:H) for use in particle detection applications. Whilst this material has been comprehensively investigated from a numerical perspective within the context of photovoltaic and imaging applications, the majority of work related to its application in particle detection has been limited to experimental studies. In this study, a material model to mimic the electrical and charge collection behavior of a-Si:H is developed using the SYNOPSYS©Technology Computer Aided Design (TCAD) simulation tool Sentaurus. The key focus of the model is concerned with the quasi-continuous defect distribution of acceptor and donor defects near the valence and conduction bands (tails states) and a Gaussian distribution of acceptor and donor defects within the mid-gap with the main parameters being the defect energy level, capture cross-section, and trap density. Currently, Sentaurus TCAD offers Poole-Frenkel mobility and trap models, however, these were deemed to be incompatible with thick a-Si:H substrates. With the addition of a fitting function, the model was able to provide acceptable agreement (within 10 nA cm−2) between simulated and experimental leakage current density for a-Si:H substrates with thicknesses of 12 and 30 μm. Additional transient simulations performed to mimic the response of the 12 μm thick device demonstrated excellent agreement (1%) with experimental data found in the literature in terms of the operating voltage required to deplete thick a-Si:H devices. The a-Si:H model developed in this work provides a method of optimizing a-Si:H based devices for particle detection applications.