Prasanna Khare

High performance extremely thin SOI (ETSOI) hybrid CMOS with Si channel NFET and strained SiGe channel PFET

For the first time, we report high performance hybrid channel ETSOI CMOS by integrating strained SiGe-channel (cSiGe) PFET with Si-channel NFET at 22nm groundrules. We demonstrate a record high speed ring oscillator (fan-out = 3) with delay of 8.5 ps/stage and 11.2 ps/stage at VDD = 0.9V and VDD = 0.7V, respectively, outperforming state-of-the-art finFET results. A novel “STI-last” integration scheme is developed to improve cSiGe uniformity and enable ultra high performance PFET with narrow widths. Furthermore, cSiGe modulates device Vt, thus providing an additional knob to enable multi-Vt while maintaining undoped channels for all devices.

UTBB FDSOI transistors with dual STI for a multi-V t strategy at 20nm node and below

We introduce an innovative dual-depth shallow trench isolation (dual STI) scheme for Ultra Thin Body and BOX (UTBB) FDSOI architecture. Since in the dual STI configuration wells are isolated from one another by the deepest trenches, this architecture enables a full use of the back bias while staying compatible with both standard bulk design and conventional SOI substrates. We demonstrate in 20nm ground rules that we are able to tune Vt by more than 400mV, that transistor performance can be boosted by up to 30% and that Ioff can be controlled over 3 decades by allowing more than VDD/2 to be applied on the back gate.

Ultra-thin-body and BOX (UTBB) fully depleted (FD) device integration for 22nm node and beyond

We present UTBB devices with a gate length (L<inf>G</inf>) of 25nm and competitive drive currents. The process flow features conventional gate-first high-k/metal and raised source/drains (RSD). Back bias (V<inf>bb</inf>) enables V<inf>t</inf> modulation of more than 125mV with a V<inf>bb</inf> of 0.9V and BOX thickness of 12nm. This demonstrates the importance and viability of the UTBB structure for multi-V<inf>t</inf> and power management applications. We explore the impact of GP, BOX thickness and V<inf>bb</inf> on local V<inf>t</inf> variability for the first time. Excellent A<inf>Vt</inf> of 1.27 mV·µm is achieved. We also present simulations results that suggest UTBB has improved scalability, reduced gate leakage (I<inf>g</inf>) and lower external resistance (R<inf>ext</inf>), thanks to a thicker inversion gate dielectric (T<inf>inv</inf>) and body (T<inf>si</inf>) thickness.

Strain engineered extremely thin SOI (ETSOI) for high-performance CMOS

High-performance strain-engineered ETSOI devices are reported. Three methods to boost the performance, namely contact strain, strained SOI (SSDOI) for NFET, and SiGe-on-insulator (SGOI) for PFET are examined. Significant performance boost is demonstrated with competitive drive currents of 1.65mA/μm and 1.25mA/μm, and I_eff of 0.95mA/μm and 0.70mA/μm at I_off =100nA/μm and V_DD of 1V, for NFET and PFET, respectively.

Ground plane optimization for 20nm FDSOI transistors with thin Buried Oxide

Planar fully depleted (FD) devices with thin Buried Oxide (BOX) offer the unique ability to incorporate effective back biasing which is a key enabler to build a versatile multi-Vt technology. From a dynamic standpoint, forward back bias lowers Vt and thus boost device performance, whereas reverse back bias increases Vt and thus decreases leakage. From a static point of view the back gate allows fine Vt tuning. Here we propose and evaluate a back gate implant scheme that enables a full use of the back bias.