[KSCI] Korea Science Citation Index Service

http://dx.doi.org/10.5573/JSTS.2010.10.3.213

Optically Controlled Silicon MESFET Fabrication and Characterizations for Optical Modulator/Demodulator

Chattopadhyay, S.N. (Department of Electrical and Computer Engineering California State University)
Overton, C.B. (Department of Electrical and Computer Engineering California State University)
Vetter, S. (Department of Electrical and Computer Engineering California State University)
Azadeh, M. (Department of Electrical and Computer Engineering California State University)
Olson, B.H. (Department of Electrical and Computer Engineering California State University)
Naga, N. El (Department of Electrical and Computer Engineering California State University)

Publication Information

JSTS:Journal of Semiconductor Technology and Science / v.10, no.3, 2010 , pp. 213-224 More about this Journal

Abstract

An optically controlled silicon MESFET (OPFET) was fabricated by diffusion process to enhance the quantum efficiency, which is the most important optoelectronic device performance usually affected by ion implantation process due to large number of process induced defects. The desired impurity distribution profile and the junction depth were obtained solely with diffusion, and etching processes monitored by atomic force microscope, spreading resistance profiling and C-V measurements. With this approach fabrication induced defects are reduced, leading to significantly improved performance. The fabricated OPFET devices showed proper I-V characteristics with desired pinch-off voltage and threshold voltage for normally-on devices. The peak photoresponsivity was obtained at 620 nm wavelength and the extracted external quantum efficiency from the photoresponse plot was found to be approximately 87.9%. This result is evidence of enhancement of device quantum efficiency fabricated by the diffusion process. It also supports the fact that the diffusion process is an extremely suitable process for fabrication of high performance optoelectronic devices. The maximum gain of OPFET at optical modulated signal was obtained at the frequency of 1 MHz with rise time and fall time approximately of 480 nS. The extracted transconductance shows the possible potential of device speed performance improvements for shorter gate length. The results support the use of a diffusion process for fabrication of high performance optoelectronic devices.

Keywords

OPFET; MESFET; etching; metallization; diffusion process; quantum efficiency; spectral responsivity; gain-bandwidth; device fabrication; characterization;

Citations & Related Records

Times Cited By KSCI : 1 (Citation Analysis)
Times Cited By SCOPUS : 0

Reference
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