Rapid thermal annealing of Be, Si, and Zn implanted GaAs using an ultrahigh power argon arc lamp
- 1 September 1983
- journal article
- Published by AIP Publishing in Applied Physics Letters
- Vol. 43 (5) , 505-507
- https://doi.org/10.1063/1.94368
Abstract
The use of a 100-kW water-walled dc argon lamp to anneal ion-implanted GaAs is reported. Annealing cycles of 3 and 10 s and peak temperatures from 950 to 1200 °C have been used to anneal Be, Si, and Zn implanted following representative implant schedules of technological importance. It is demonstrated that this technique is superior to conventional furnace anneal techniques in terms of the doping profiles, peak carrier concentrations, activation efficiencies (particularly at high doses), and mobilities achieved. The annealing technique should be applicable to large volume GaAs integrated circuit production and 100-mm-diam wafers can be annealed in a single exposure with better than 2% temperature uniformity (Si data).Keywords
This publication has 10 references indexed in Scilit:
- Rapid thermal annealing of Se and Be implanted InP using an ultrahigh power argon arc lampApplied Physics Letters, 1983
- Infrared rapid thermal annealing of Si-implanted GaAsApplied Physics Letters, 1982
- An Open‐Tube Method for Diffusion of Zinc into GaAsJournal of the Electrochemical Society, 1982
- Transient annealing of selenium-implanted gallium arsenide using a graphite strip heaterApplied Physics Letters, 1982
- Incoherent annealing of implanted layers in GaAsIEEE Electron Device Letters, 1982
- Radiation Annealing of GaAs Implanted with SiJapanese Journal of Applied Physics, 1981
- Zn Diffusion in InxGa1-xAs with ZnAs2SourceJapanese Journal of Applied Physics, 1980
- Electrical profiling and optical activation studies of Be-implanted GaAsJournal of Applied Physics, 1977
- Uniform-carrier-concentration p-type layers in GaAs produced by beryllium ion implantationApplied Physics Letters, 1976
- Electrical Behavior of Group III and V Implanted Dopants in SiliconJournal of Applied Physics, 1969