Minimizing R/sub bb/, C/sub ca/, and C/sub cb/ is crucial to maximizing the key figure of merit f/sub max/ in the SiGe HBT. Through a systematic scaling study of the extrinsic base-emitter sidewall spacer, we explore for the first time the trade-off advantages in minimizing these parasitics in the self-aligned, epitaxial-base SiGe HBT process compared with traditional ion-implanted BJT designs. We demonstrate a wide process window for the spacer thickness that achieves high f/sub T/ and f/sub max/ without significantly impacting the emitter-base breakdown voltage, the reverse emitter-base leakage, or reliability. By examining the temperature dependence of this leakage current, we establish a transition of the dominant leakage mechanism from impact ionization to band-to-band tunneling as the sidewall spacer is thinned. In addition, we demonstrate an increase in long-term /spl beta/ degradation with spacer thinning. Together, these results confirm the encroachment of extrinsic base doping upon the emitter edge as the limiting factor in the scaling process.
[1]
J. Cressler,et al.
Si/SiGe epitaxial-base transistors. I. Materials, physics, and circuits
,
1995
.
[2]
J. Stork,et al.
Tunneling in base-emitter junctions
,
1983,
IEEE Transactions on Electron Devices.
[3]
David J. Roulston,et al.
Bipolar Semiconductor Devices
,
1990
.
[4]
C. T. Chuang.
Performance degradation due to extrinsic base encroachment in advanced narrow-emitter bipolar circuits. II. Non-threshold logic circuits
,
1989
.
[5]
James D. Warnock,et al.
Silicon bipolar device structures for digital applications: technology trends and future directions
,
1995
.
[6]
Ching-Te Chuang,et al.
The effect of extrinsic base encroachment on the switch-on transient of advanced narrow-emitter bipolar transistors
,
1988
.