Title :
Resonant-cavity separate absorption, charge and multiplication avalanche photodiodes with high-speed and high gain-bandwidth product
Author :
Nie, H. ; Anselm, K.A. ; Lenox, C. ; Yuan, P. ; Hu, C. ; Kinsey, G. ; Streetman, B.G. ; Campbell, J.C.
Author_Institution :
Microelectron. Res. Center, Texas Univ., Austin, TX, USA
fDate :
3/1/1998 12:00:00 AM
Abstract :
Previously, it has been shown that resonant-cavity separate-absorption-and-multiplication (SAM) avalanche photodiodes (APD´s) exhibit high-speed and high gain-bandwidth products. In this letter, we describe a resonant-cavity SAM APD with an additional charge layer that provides better control of the electric field profile. These devices have achieved bandwidths as high as 33 GHz in the low-gain regime and a record gain-bandwidth product of 290 GHz. We also describe the correlation between the gain-bandwidth product and the doping level in the charge layer. With width dependent ionization coefficients, the current versus voltage (I-V) and gain-bandwidth simulations agree well with the measured results and indicate that even higher gain-bandwidth should be achievable with an optimized SACM APD structure.
Keywords :
avalanche photodiodes; high-speed optical techniques; optical communication equipment; optical resonators; photodetectors; 290 GHz; 33 GHz; SAM avalanche photodiodes; additional charge layer; doping level; electric field profile; gain-bandwidth product; gain-bandwidth simulations; high gain-bandwidth product; high gain-bandwidth products; high-speed; higher gain-bandwidth; ionization coefficients; optimized SACM APD structure; resonant-cavity SAM APD; resonant-cavity separate absorption charge and multiplication avalanche photodiodes; Absorption; Avalanche photodiodes; Bandwidth; Dark current; Doping; Gallium arsenide; Ionization; Mirrors; Optical noise; Resonance;
Journal_Title :
Photonics Technology Letters, IEEE
