Enhanced performance in 50 nm N-MOSFETs with silicon-carbon source/drain regions

Enhanced performance in 50 nm N-MOSFETs with silicon-carbon source/drain regions

This paper reports a novel strained N-channel transistor structure with sub-100 nm gate lengths. The strained N-MOSFET features silicon-carbon (SiC) source and drain (S/D) regions formed by a Si recess etch and a selective epitaxy of SiC in the S/D regions. The carbon mole fraction incorporated is 1...

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Hauptverfasser: Kah Wee Ang, King Jien Chui, Bliznetsov, V., Anyan Du, Balasubramanian, N., Ming Fu Li, Ganesh Samudra, Yee-Chia Yeo
Format: Tagungsbericht
Sprache:eng
Schlagworte:
Applied sciences
Electron mobility
Electronics
Epitaxial growth
Exact sciences and technology
Heterojunctions
Implants
Intrusion detection
Microelectronic fabrication (materials and surfaces technology)
Microelectronics
MOSFET circuits
Semiconductor electronics. Microelectronics. Optoelectronics. Solid state devices
Silicon carbide
Sputter etching
Tensile strain
Transistors
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Zusammenfassung:This paper reports a novel strained N-channel transistor structure with sub-100 nm gate lengths. The strained N-MOSFET features silicon-carbon (SiC) source and drain (S/D) regions formed by a Si recess etch and a selective epitaxy of SiC in the S/D regions. The carbon mole fraction incorporated is 1.3%. Lattice mismatch of /spl sim/0.65% between SiC and Si results in horizontal tensile strain and vertical compressive strain in the Si channel region, both contributing to substantial electron mobility enhancement. The conduction band offset /spl Delta/E/sub c/ between the SiC source and the strained-Si channel also contributes to increased electron injection velocity from the source. Implementation of the SiC stressors provides significant drive current I/sub DS/ enhancement in the N-MOSFETs. I/sub DS/ enhancement of 50% was observed for a gate length of 50 nm.
DOI:10.1109/IEDM.2004.1419383