Title :
Low temperature operation of Si and SiGe bipolar transistors
Author :
Crabbe, E.F. ; Patton, G.L. ; Stork, J.M.C. ; Comfort, J.H. ; Meyerson, B.S. ; Sun, J.Y.-C.
Author_Institution :
IBM Thomas J. Watson Res. Center, Yorktown Heights, NY, USA
Abstract :
The operation of Si and SiGe epitaxial-base bipolar transistors at liquid nitrogen temperature is demonstrated to be comparable or superior to that at room temperature. Tunneling leakage at the emitter-base junction is suppressed at all temperatures as a result of a lightly doped spacer. The maximum current gain of both the Si and the SiGe devices shows a very small temperature dependence. Monte Carlo simulations of a Si-base transistor at 77 K indicate the presence of velocity overshoot, which is supported by the higher current density at the onset of base pushout. The peak cutoff frequency at 85 K is 57 GHz for the Si transistor and 94 GHz for the SiGe transistor, respectively 8% and 25% higher than at 298 K.<>
Keywords :
Ge-Si alloys; Monte Carlo methods; bipolar transistors; elemental semiconductors; semiconductor device models; semiconductor materials; silicon; 57 GHz; 77 K; 85 K; 94 GHz; Monte Carlo simulations; Si; SiGe bipolar transistors; base pushout; current density; emitter-base junction; epitaxial-base bipolar transistors; lightly doped spacer; liquid nitrogen temperature; maximum current gain; peak cutoff frequency; tunnelling leakage; velocity overshoot; Bipolar transistors; Current density; Cutoff frequency; Germanium silicon alloys; Nitrogen; Silicon germanium; Temperature dependence; Tunneling;
Conference_Titel :
Electron Devices Meeting, 1990. IEDM '90. Technical Digest., International
Conference_Location :
San Francisco, CA, USA
DOI :
10.1109/IEDM.1990.237236
