Current transport mechanisms in GaN-based metal–semiconductor–metal photodetectors
- 2 February 1998
- journal article
- Published by AIP Publishing in Applied Physics Letters
- Vol. 72 (5), 542-544
- https://doi.org/10.1063/1.120752
Abstract
We report on the current transport mechanisms dominant at the Schottky interface of metal–semiconductor–metal photodetectors fabricated on single-crystal GaN, with active layers of 1.5 and 4.0 μm thickness. We have modeled transport in the 1.5 μm devices using thermionic emission theory, and in the 4.0 μm devices using thermionic field emission theory. We have obtained a good fit to the experimental data. We hypothesize that traps in the GaN are related to a combination of surface defects (possibly threading dislocations), and deep-level bulk states that are within a tunneling distance of the interface. A simple qualitative model is presented.This publication has 6 references indexed in Scilit:
- Properties of a photovoltaic detector based on an n-type GaN Schottky barrierJournal of Applied Physics, 1997
- Very low dark current metal–semiconductor–metal ultraviolet photodetectors fabricated on single-crystal GaN epitaxial layersApplied Physics Letters, 1997
- Microstructure of Ti/Al and Ti/Al/Ni/Au Ohmic contacts for n-GaNApplied Physics Letters, 1996
- Characterisation of Pd Schottky barrier on n-type GaNElectronics Letters, 1996
- Shallow and Deep Level Defects in GaNMRS Proceedings, 1995
- Analysis of deep levels in n-type GaN by transient capacitance methodsJournal of Applied Physics, 1994