Kelvin S. K. Kwa scite author profile

Effective negative capacitance has been postulated in ferroelectrics because there is a hysteresis in plots of polarization-electric field. Compelling experimental evidence of effective negative capacitance is presented here at room temperature in engineered devices, where it is stabilized by the presence of a paraelectric material. In future integrated circuits, the incorporation of such negative capacitance into MOSFET gate stacks would reduce the subthreshold slope, enabling low power operation and reduced self-heating.

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Effect of deposition conditions and post deposition anneal on reactively sputtered titanium nitride thin films

Ponon

et al. 2015

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Impact of strained-Si thickness and Ge out-diffusion on gate oxide quality for strained-Si surface channel n-MOSFETs

Dalapati

Chattopadhyay

Kwa

et al. 2006

IEEE Trans. Electron Devices

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A model for capacitance reconstruction from measured lossy MOS capacitance voltage characteristics

Kwa

Chattopadhyay

Janković

et al. 2002

Semicond. Sci. Technol.

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A capacitance model is developed and a correction formula is derived to reconstruct the intrinsic oxide capacitance value from measured capacitance and conductance of lossy MOS devices. Due to discrepancies during processing, such as cleaning, an unwanted lossy dielectric layer is present in the oxide/semiconductor interface causing the measured capacitance in strong accumulation to be frequency dependent. The capacitance-voltage characteristics after correction are free from any frequency dispersion effect and give the actual oxide thickness in accumulation at all frequencies. Simulation of the measured capacitance-frequency curve was carried out using the model. The model was applied to SiO 2 /Si, SiO 2 /strained Si and GaO 2 /GaAs MOS capacitors.

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High-performance nMOSFETs using a novel strained Si/SiGe CMOS architecture

Olsen

O'Neill

Driscoll

et al. 2003

IEEE Trans. Electron Devices

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Abstract-Performance enhancements of up to 170% in drain current, maximum transconductance, and field-effect mobility are presented for nMOSFETs fabricated with strained-Si channels compared with identically processed bulk Si MOSFETs. A novel layer structure comprising Si/Si 0 7 Ge 0 3 on an Si 0 85 Ge 0 15 virtual substrate (VS) offers improved performance advantages and a strain-compensated structure. A high thermal budget process produces devices having excellent on/off-state drain-current characteristics, transconductance, and subthreshold characteristics. The virtual substrate does not require chemical-mechanical polishing and the same performance enhancement is achieved with and without a titanium salicide process.

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Kelvin S. K. Kwa

Experimental Observation of Negative Capacitance in Ferroelectrics at Room Temperature

Effect of deposition conditions and post deposition anneal on reactively sputtered titanium nitride thin films

Impact of strained-Si thickness and Ge out-diffusion on gate oxide quality for strained-Si surface channel n-MOSFETs

A model for capacitance reconstruction from measured lossy MOS capacitance voltage characteristics

High-performance nMOSFETs using a novel strained Si/SiGe CMOS architecture

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