# High-Temperature Photocurrent Mechanism of \b{eta}-Ga2O3 Based MSM   Solar-Blind Photodetectors

**Authors:** B. R. Tak, Manjari Garg, Sheetal Dewan, Carlos G. Torres-Castanedo,, Kuang-Hui Li, Vinay Gupta, Xiaohang Li, R. Singh

arXiv: 1812.07197 · 2019-05-01

## TL;DR

This study investigates the high-temperature performance and photocurrent mechanisms of ta-Ga2O3 MSM UV photodetectors, revealing temperature-dependent behaviors and the influence of electron-phonon interactions crucial for high-temperature applications.

## Contribution

It provides new insights into the high-temperature photocurrent mechanisms of ta-Ga2O3 MSM photodetectors, including temperature effects on photocurrent and carrier dynamics.

## Key findings

- Photocurrent to dark current ratio remains high at room temperature.
- Photocurrent behavior varies with temperature, decreasing then increasing up to 2500C.
- Suppression of the blue band indicates instability of self-trapped holes.

## Abstract

High-temperature operation of metal-semiconductor-metal (MSM) UV photodetectors fabricated on pulsed laser deposited \b{eta}-Ga2O3 thin films has been investigated. These photodetectors were operated up to 250 {\deg}C temperature under 255 nm illumination. The photo current to dark current (PDCR) ratio of about 7100 was observed at room temperature (RT) while it had a value 2.3 at 250 {\deg}C at 10 V applied bias. A decline in photocurrent was observed from RT to 150 {\deg}C and then it increased with temperature up to 250 {\deg}C. The suppression of the blue band was also observed from 150 {\deg}C temperature which indicated that self-trapped holes in Ga2O3 became unstable. Temperature-dependent rise and decay times of carriers were analyzed to understand the photocurrent mechanism and persistence photocurrent at high temperatures. Coupled electron-phonon interaction with holes was found to influence the photoresponse in the devices. The obtained results are encouraging and significant for high-temperature applications of \b{eta}-Ga2O3 MSM deep UV photodetectors.

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Source: https://tomesphere.com/paper/1812.07197