Band-Gap Engineering: From Physics and Materials to New Semiconductor Devices
- 9 January 1987
- journal article
- research article
- Published by American Association for the Advancement of Science (AAAS) in Science
- Vol. 235 (4785), 172-176
- https://doi.org/10.1126/science.235.4785.172
Abstract
Band-gap engineering is a powerful technique for the design of new semiconductor materials and devices. Heterojunctions and modern growth techniques, such as molecular beam epitaxy, allow band diagrams with nearly arbitrary and continuous band-gap variations to be made. The transport properties of electrons and holes can be independently and continuously tuned for a given application. A new generation of devices with unique capabilities, ranging from solid-state photomultipliers to resonant tunneling transistors, is emerging from this approach.Keywords
This publication has 38 references indexed in Scilit:
- Dual-band step-impedance bandpass filter for multimode wireless LANsElectronics Letters, 2004
- Dipole-Induced Changes of the Band Discontinuities at the Si-Si InterfacePhysical Review Letters, 1986
- Conversion of Poisson Photons into Sub-Poisson Photons by the Action of Electron FeedbackPhysical Review Letters, 1986
- New Quantum Photoconductivity and Large Photocurrent Gain by Effective-Mass Filtering in a Forward-Biased SuperlatticeJunctionPhysical Review Letters, 1985
- Quantum well oscillatorsApplied Physics Letters, 1984
- New Transient Electrical Polarization Phenomenon in Sawtooth SuperlatticesPhysical Review Letters, 1983
- n-i-p-i doping superlattices—metastable semiconductors with tunable propertiesJournal of Vacuum Science & Technology B, 1983
- Enhancement of electron impact ionization in a superlattice: A new avalanche photodiode with a large ionization rate ratioApplied Physics Letters, 1982
- Quantum-well heterostructure lasersIEEE Journal of Quantum Electronics, 1980
- JUNCTION LASERS WHICH OPERATE CONTINUOUSLY AT ROOM TEMPERATUREApplied Physics Letters, 1970