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A cost competitive 20nm technology node is described that enabled industry-first 20nm cellular modem chip with 2× peak data rates vs 28nm, and 2× carrier aggregation. Process and design enhancements for layout context optimization, and continuous process improvements resulted in 18% boost in circuit performance while simultaneously achieving >30% power reduction. 3 mask local interconnect and 64nm...
The authors explored some of the challenges of the extremely thin SOI technology for mainstream CMOS. Faceted RSD was used to minimize parasitic capacitance. PFET performance is competitive with best bulk CMOS technologies, while NFET performance can be increased by further reduction in the series resistance. The impact of silicon thickness on the device variability was studied to quantify wafer uniformity...
The root causes of the high voltage (HV) LDMOS (Fig. 2) failed at the low voltage electrostatic-discharge (ESD) zap is found. One is caused by the bulk layout and one is caused by the intrinsic characteristic of the device. From the findings, a new structure is proposed to eliminate the root causes without sacrificing the IV characteristics and dimension of the device.
We present a new ETSOI CMOS integration scheme. The new process flow incorporates all benefits from our previous unipolar work. Only a single mask level is required to form raised source/drain (RSD) and extensions for both NFET and PFET. Another new feature of this work is the incorporation of two strain techniques to boost performance, (1) Si:C RSD for NFET and SiGe RSD for PFET, and (2) enhanced...
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