Title :
Monte Carlo simulation of the effect of multiplication layer thickness in wide-bandwidth avalanche photodiodes
Author :
Chandramouli, Varun ; Maziar, C.M. ; Campbell, Joe C.
Author_Institution :
Dept. of Electr. & Comput. Eng., Texas Univ., Austin, TX
fDate :
11/1/1993 12:00:00 AM
Abstract :
Summary form only given. The impact ionization process was studied in thin multiplication layers used in wide-bandwidth SAGM-APDs (separate absorption, grading, and multiplication avalanche photodiodes) using wave-vector-dependent threshold energies for impact ionization and a full-band Monte Carlo model. Results show that the number of ionizing collisions is reduced in thin layers, leading to an increase in the effective β/α ratio and explaining the experimentally observed reduction in the excess noise factor. It is also shown that, even though the values of α and β in III-V semiconductors converge at high electric fields, it is possible to use thin multiplication regions to reduce the excess noise factor and at the same time increase the bandwidth of the device operation
Keywords :
Monte Carlo methods; avalanche photodiodes; impact ionisation; semiconductor device models; semiconductor device noise; SAGM-APDs; effective β/α ratio; excess noise factor; full-band Monte Carlo model; impact ionization process; ionizing collisions; multiplication layer thickness; separate absorption, grading, and multiplication; thin multiplication regions; wave-vector-dependent threshold energies; wide-bandwidth avalanche photodiodes; Acoustic scattering; Brillouin scattering; Charge carrier processes; Electron optics; Impact ionization; Indium phosphide; Monte Carlo methods; Noise reduction; Optical scattering; Semiconductor device noise;
Journal_Title :
Electron Devices, IEEE Transactions on
