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A leading edge 14 nm SoC platform technology based upon the 2nd generation Tri-Gate transistor technology [5] has been optimized for density, low power and wide dynamic range. 70 nm gate pitch, 52 nm metal pitch and 0.0499 um2 HDC SRAM cells are the most aggressive design rules reported for 14/16 nm node SoC process to achieve Moore's Law 2x density scaling over 22 nm node. High performance NMOS/PMOS...
A leading edge 14 nm SoC platform technology based upon the 2nd generation Tri-Gate transistor technology [5] has been optimized for density, low power and wide dynamic range. 70 nm gate pitch, 52 nm metal pitch and 0.0499 um2 HDC SRAM cells are the most aggressive design rules reported for 14/16 nm node SoC process to achieve Moore's Law 2x density scaling over 22 nm node. High performance NMOS/PMOS...
A leading edge 22nm 3-D tri-gate transistor technology has been optimized for low power SoC products for the first time. Low standby power and high voltage transistors exploiting the superior short channel control, < 65mV/dec subthreshold slope and <40mV DIBL, of the Tri-Gate architecture have been fabricated concurrently with high speed logic transistors in a single SoC chip to achieve industry...
Beyond 65nm node, pattern loading effect (PLE) in conventional RTP (front-side heating) has been emerged as a major yield killer. Different pattern and deposited film property strongly influence thermal absorption and emission at the integration stage of the spike anneal (e.g., STI, poly, and nitride spacers) lead to significant temperature differences across each die. Several methods for reducing...
In this paper, we have demonstrated that cryogenic implantation applied to source and drain (SD) extension, pocket/halo and SD formation offers advantages for higher core and SRAM driving current and one order lower Ioff bulk (Ioffb) leakage in NMOS with reduced SRAM defectivity. Atomistic Kinetic Monte Carlo (KMC) modeling confirms that the cryo-implantation has enabled a unique control of active...
A 32nm RF SOC technology is developed with high-k/metal-gate triple-transistor architecture simultaneously offering devices with high performance and very low leakage to address advanced RF/mobile communications markets. A high performance NMOS achieves an fT of 420GHz. Concurrently, a low leakage 30pA/um NMOS achieves an fT of 218GHz. Deep-nwell/guard rings improves noise isolation by >50dB. High...
A leading edge 32 nm high-k/metal gate transistor technology has been optimized for SoC platform applications that span a wide range of power, performance, and feature space. This technology has been developed to be modular, offering mix-and-match transistors, interconnects, RF/analog passive elements, embedded memory, and noise mitigation options. The low gate leakage of the high-k gate dielectric...
A leading edge 45 nm CMOS system-on-chip (SOC) technology using Hafnium-based high-k/metal gate transistors has been optimized for low power products. PMOS/NMOS logic transistor drive currents of 0.86/1.08 mA/um, respectively, have been achieved at 1.1 V and off-state leakage of 1 nA/um. Record RF performance for a mainstream 45 nm bulk CMOS technology has been achieved with measured fT/fMAX values...
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