Title :
Quantum-dot resonant-cavity separate absorption, charge, and multiplication avalanche photodiode operating at 1.06 μm
Author :
Nie, H. ; Baklenov, O. ; Yuan, P. ; Lenox, C. ; Streetman, B.G. ; Campbell, J.C.
Author_Institution :
Dept. of Electr. & Comput. Eng., Texas Univ., Austin, TX, USA
fDate :
7/1/1998 12:00:00 AM
Abstract :
We report on the design, fabrication and performance of a quantum-dot (QD) resonant-cavity separate absorption, charge, and multiplication avalanche photodiode (APD). The device was grown on GaAs using molecular beam epitaxy and was designed to detect light near 1.06 μm. The absorbing region consists of a stack of five self-assembled QD layers, that were formed by the deposition of six monolayers of In/sub 0.5/Ga/sub 0.5/As, with GaAs spacer layers. The peak efficiency at 1.06 μm is 57% with a spectral bandwidth of 1.3 nm. The photodiode exhibits low dark current, low multiplication noise (k<0.3), good gain characteristics and a low-breakdown voltage (/spl sim/15 V), which is much lower than that of Si-based APD´s operating at 1.06 μm.
Keywords :
avalanche photodiodes; dark conductivity; gallium arsenide; infrared detectors; monolayers; optical design techniques; optical fabrication; optical films; optical noise; optical resonators; photodetectors; semiconductor quantum dots; 1.06 mum; 15 V; 57 percent; GaAs; GaAs spacer layers; In/sub 0.5/Ga/sub 0.5/As; Si-based APD; absorbing region; detect light; good gain characteristics; low dark current; low multiplication noise; low-breakdown voltage; molecular beam epitaxy; monolayers; optical design; optical fabrication; peak efficiency; quantum-dot resonant-cavity separate absorption charge and multiplication avalanche photodiode; self-assembled QD layers; spectral bandwidth; Absorption; Avalanche photodiodes; Bandwidth; Dark current; Fabrication; Gallium arsenide; Molecular beam epitaxial growth; Quantum dots; Resonance; Voltage;
Journal_Title :
Photonics Technology Letters, IEEE
