Title :
Avalanche Multiplication in InAlAs
Author :
Goh, Y.L. ; Massey, D.J. ; Marshall, A.R.J. ; Ng, J.S. ; Tan, C.H. ; Ng, W.K. ; Rees, G.J. ; Hopkinson, M. ; David, J.P.R. ; Jones, S.K.
Author_Institution :
Dept. of Electron. & Electr. Eng., Univ. of Sheffield
Abstract :
A systematic study of avalanche multiplication on a series of In 0.52Al0.48As p+-i-n+ and n +-i-p+ diodes with nominal intrinsic region thicknesses ranging from 0.1 to 2.5 mum has been used to deduce effective ionization coefficients between 220 and 980 kVmiddotcm-1. The electron and hole ionization coefficient ratio varies from 32.6 to 1.2 with increasing field. Tunneling begins to dominate the bulk current prior to avalanche breakdown in the 0.1-mum-thick structure, imposing an upper limit to the operating field. While the local model can accurately predict the breakdown in the diodes, multiplication is overestimated at low fields. The effects of ionization dead space, which becomes more significant as the intrinsic region thickness reduces, can be corrected for by using a simple correction technique
Keywords :
III-V semiconductors; aluminium compounds; avalanche breakdown; avalanche photodiodes; impact ionisation; indium compounds; p-i-n photodiodes; semiconductor device breakdown; 0.1 to 2.5 micron; In0.52Al0.48sAs n+-i-p+ diodes; In0.52Al0.48sAs p+-i-n+ diodes; InAlAs; avalanche breakdown; avalanche multiplication; electron ionization coefficient ratio; hole ionization coefficient ratio; ionization dead space; Absorption; Charge carrier processes; Diodes; Electric breakdown; Heterojunctions; Indium compounds; Indium gallium arsenide; Indium phosphide; Ionization; Photonic band gap; Avalanche photodiodes (APDs); impact ionization; ionization coefficients; multiplication;
Journal_Title :
Electron Devices, IEEE Transactions on
DOI :
10.1109/TED.2006.887229
