Peter J. Geiss

Comparison of transformation to low-resistivity phase and agglomeration of TiSi/sub 2/ and CoSi/sub 2/

The phase transformation and stability of TiSi/sub 2/ on n/sup +/ diffusions are investigated. Narrower n/sup +/ diffusions require higher anneal temperatures, or longer anneal times, than wider diffusions for complete transitions from the high-resistivity C49 phase to the low-resistivity C54 phase. A model is presented which explains this in terms of the probability of forming C54 nuclei on narrow diffusions and the influence of diffusion width on C54 grain size. The results are that more C49 and C54 nucleation events are required to completely transform narrow lines. For thin TiSi/sub 2/ (40 nm), there is a narrow process window for achieving complete transformation without causing agglomeration of the TiSi/sub 2/. The process window decreases with decreasing silicide thickness. A significantly larger process window is achieved with short-time rapid annealing. Similar studies are performed for CoSi/sub 2/ on n/sup +/ and p/sup +/ diffusions. No linewidth dependence is observed for the transformation from CoSi/sub x/ to CoSi/sub 2/. There is a broad process window from 575 degrees C to 850 degrees C using furnace annealing, for which the low-resistivity phase is obtained without causing agglomeration. >

A 0.18 /spl mu/m BiCMOS technology featuring 120/100 GHz (f/sub T//f/sub max/) HBT and ASIC-compatible CMOS using copper interconnect

A BiCMOS technology is presented that integrates a high performance NPN (f/sub T/=120 GHz and f/sub max/=100 GHz), ASIC compatible 0.11 /spl mu/m L/sub eff/ CMOS, and a full suite of passive elements. Significant HBT performance enhancement compared to previously published results has been achieved through further collector and base profile optimization guided by process and device simulations. Base transit time reduction was achieved by simultaneously increasing the Ge ramp and by limiting the base diffusion with the addition of carbon doping to SiGe epitaxial base. This paper describes IBMs next generation SiGe BiCMOS production technology targeted at the communications market.

A 0.24 /spl mu/m SiGe BiCMOS mixed-signal RF production technology featuring a 47 GHz f/sub t/ HBT and 0.18 /spl mu/m L/sub ett/ CMOS

A new base-after-gate integration scheme has been developed to integrate a 47 GHz f/sub t/, 65 GHz F/sub max/SiGe HBT process with a 0.24 /spl mu/m CMOS technology having 0.18 /spl mu/m L/sub eff/ and 5 nm gate oxide. We discuss the benefits and challenges of this integration scheme which decouples the HBT from the CMOS thermal cycles. We also describe the resulting 0.24 /spl mu/m SiGe BiCMOS technology, BiCMOS 6HP, which includes a 7 nm dual gate oxide option and full suite of passive components. The technology provides a high level of integration for mixed-signal RF applications.

High performance, low complexity 0.18 /spl mu/m SiGe BiCMOS technology for wireless circuit applications

High frequency performance at low current density and low wafer cost is essential for low power wireless BiCMOS technologies. We have developed a low-complexity, ASIC-compatible, 0.18 /spl mu/m SiGe BiCMOS technology for wireless applications that offers 3 different breakdown voltage NPNs; with the high performance device achieving F/sub t//F/sub max/ of 60/85 GHz with a 3.0 V BV/sub CEO/. In addition, a full suite of high performance passive devices complement the state-of-the-art SiGe wireless HBTs.