Normal incidence intervalence subband absorption in GaSb quantum well enhanced by coupling to InAs conduction band
- 8 February 1993
- journal article
- research article
- Published by AIP Publishing in Applied Physics Letters
- Vol. 62 (6) , 609-611
- https://doi.org/10.1063/1.108871
Abstract
We demonstrate a novel infrared (IR) detector structure based on the type II p‐doped InAs/GaSb multiquantum well system. Due to the coupling of the first conduction subband in InAs to the valence band states in GaSb, the normal incidence absorption coefficient for intervalence subband transitions between heavy and light hole subbands in GaSb quantum wells is significantly enhanced. An absorption coefficient as large as 6500 cm−1 has been achieved in the wavelength range of 8–17 μm. This is the strongest absorption ever observed among all the IR materials in this wavelength range.Keywords
This publication has 12 references indexed in Scilit:
- Normal incidence intersubband optical transition in GaSb/InAs superlatticesApplied Physics Letters, 1992
- Normal incidence infra-red absorption from intersub-band transitions in p -type GaInAs/AIInAs quantum wellsElectronics Letters, 1992
- Normal incidence infrared photoabsorption in p-type GaSb/GaxAl1−xSb quantum wellsJournal of Applied Physics, 1992
- Normal incidence hole intersubband absorption long wavelength GaAs/AlxGa1−xAs quantum well infrared photodetectorsApplied Physics Letters, 1991
- 10 μm infrared hot-electron transistorsApplied Physics Letters, 1990
- Resonant interband coupling in single-barrier heterostructures of InAs/GaSb/InAs and GaSb/InAs/GaSbJournal of Applied Physics, 1990
- New 10 μm infrared detector using intersubband absorption in resonant tunneling GaAlAs superlatticesApplied Physics Letters, 1987
- Strong 8.2 μm infrared intersubband absorption in doped GaAs/AlAs quantum well waveguidesApplied Physics Letters, 1987
- Spatial separation of carriers in InAs–GaSb superlatticesJournal of Vacuum Science and Technology, 1981
- Optical absorption of In1−xGaxAsGaSb1−yAsy superlatticesSolid State Communications, 1978