Sheng-Da Liu

5nm-gate nanowire FinFET

A new nanowire FinFET structure is developed for CMOS device scaling into the sub-10 nm regime. Accumulation mode P-FET and inversion mode N-FET with 5 nm and 10 nm physical gate length, respectively, are fabricated. N-FET gate delay (CV/I) of 0.22 ps and P-FET gate delay of 0.48 ps with excellent subthreshold characteristics are achieved, both with very low off leakage cur-rent less than 10 nA/ /spl mu/m. Nanowire FinFET device operation is also explored using 3-D full quantum mechanical simulation.

20nm gate bulk-finFET SONOS flash

High-performance FinFET SONOS (silicon-oxide-nitride-oxide-silicon) flash cells with gate length down to 20nm have been fabricated and operated successfully on bulk-silicon substrate for the first time. A program/erase window of 2V has been achieved with high P/E speed (TP equiv 10mus and TE equiv 1ms), and a 1.5V window remained after 10 years at room temperature. Multi-level storage is also obtained with DeltaVt > 4V and TP,E equiv 1 ms. Operation voltages are not more than 7V in the two applications. Gate disturb issues are alleviated by applying an appropriate bias on unselected bit lines

A next generation CMOS-compatible GaN-on-Si transistors for high efficiency energy systems

CMOS-compatible 100 V / 650 V enhancement-mode high electron mobility transistors (E-HEMTs) and 650 V depletion-mode MISFET (D-MISFET) are fabricated on 6-inch GaN-on-Si wafers. These devices show excellent power converter switching performances. Both 100 V and 650 V E-HEMTs had passed industrial reliability qualifications. The importance of bulk leakage, interface quality and gate trapping in dynamic on-resistance is figured out. The device with optimized processes shows a significant reduction of the dynamic on-resistance degradation.

Novel 20nm hybrid SOI/bulk CMOS technology with 0.183/spl mu/m/sup 2/ 6T-SRAM cell by immersion lithography

For the first time, a novel hybrid SOI/bulk CMOS technology with 20nm gate length and low-leakage 1.3nm thick SiON gate dielectric has been developed for advanced SOC applications. 26% (for N-FET) and 35% (for P-FET) improvements of intrinsic gate delay (CV/I) at low gate leakage of 20-40A/cm/sup 2/ have been achieved over previous leading-edge 45nm node version, while maintaining the same sub-threshold leakage (100nA//spl mu/m). 10 times reduction of the leakage can be further modulated by a virtual back-gate control. Fine patterning with line pitch of 90nm by immersion lithography is demonstrated, which features 0.183/spl mu/m/sup 2/ 6T-SRAM cell for 32nm node on-trend scaling.

45nm node planar-SOI technology with 0.296 /spl mu/m/sup 2/ 6T-SRAM cell

The first 45nm node planar-SOI technology has been developed with 6T-SRAM cell of 0.296 /spl mu/m/sup 2/. An adequate static noise margin of 120mV is obtained even at 0.6V operation. Fine patterning with line pitch of 130nm and contact pitch of 140nm by optical lithography is demonstrated. Transistors with 30nm gate length and 27nm slim spacer operate at 1V/0.85V with excellent drive currents of 1000/740 and 530/420 /spl mu/A//spl mu/m for N-FET and P-FET, respectively. The P-FET current is the best reported so far.

Improved trap-related characteristics on SiN x /AlGaN/GaN MISHEMTs with surface treatment

In this paper, the reliable SiNx/AlGaN/GaN MISHEMTs on silicon substrate with improved trap-related characteristics have been well demonstrated. The devices with our proposed treatment method showed less deep-level traps and more Si surface donors at SiNx-AlGaN interface. The trap related device characteristics are also improved by using our optimized treatment method. The devices with proposed treatment method exhibit less current collapse and better positive bias temperature stability of threshold voltage. All the results suggest that the proposed treatment method is very effective to improve the slow-trap related device reliability.