Title :
Dark-Current Suppression in Metal–Germanium–Metal Photodetectors Through Dopant-Segregation in NiGe—Schottky Barrier
Author :
Zang, H. ; Lee, S.J. ; Loh, W.-Y. ; Wang, J. ; Chua, K.T. ; Yu, M.B. ; Cho, B.J. ; Lo, G.Q. ; Kwong, D.-L.
Author_Institution :
Inst. of Microelectron., Singapore
Abstract :
We demonstrate, for the first time, the application of dopant-segregation (DS) technique in metal-germanium- metal photodetectors for dark-current suppression and high-speed performance. Low defect density and surface smooth epi-Ge (~300 nm) layer was selectively grown on patterned Si substrate using two-step epi-growth at 400degC/600degC combined with a thin (~10 nm) low-temperature Si/Si0.8 Ge0.2 buffer layer. NiGe with DS effectively modulates the Schottky barrier height and suppresses dark current to ~10 -7 A at -1 V bias (width/spacing: 30/2.5 mum). Under normal incidence illumination at 1.55 mum, the devices show photoresponsivity of 0.12 A/W. The 3 dB bandwidth under - 1 V bias is up to 6 GHz.
Keywords :
Schottky barriers; buffer layers; contact resistance; dark conductivity; doping; elemental semiconductors; germanium; germanium alloys; integrated optoelectronics; nickel alloys; optical communication; photodetectors; surface segregation; Ge-NiGe; Schottky barrier; Si; Si-Si0.8Ge0.2; buffer layer; contact resistance; dark-current suppression; defect density; dopant-segregation technique; frequency 6 GHz; metal-germanium-metal photodetectors; optical communications; photoresponsivity; sheet resistance; silicon substrate; surface smooth epilayer; temperature 400 degC; temperature 600 degC; voltage -1 V; wavelength 1.55 mum; Bandwidth; Buffer layers; Contact resistance; Dark current; Electrodes; Microelectronics; Photodetectors; Schottky barriers; Substrates; Temperature; Dark current; dopant segregation (DS); germanium; optical communications; photodetectors; selective epitaxial;
Journal_Title :
Electron Device Letters, IEEE
DOI :
10.1109/LED.2007.914095
