论文信息 - Thermal analysis of ultra-thin body device scaling [SOI and FinFet devices]

Thermal analysis of ultra-thin body device scaling [SOI and FinFet devices]

This paper explores the effect of confined dimensions and complicated geometries on the self-heating of ultra-thin body SOI and FinFET devices. A compact thermal model is introduced, incorporating the most advanced understanding of nanoscale heat conduction available. Novel device scaling is analyzed from a thermal point of view. We show device temperatures are very sensitive to the choice of drain and channel extension dimensions, and suggest a parameter design space which can help alleviate thermal problems. ITRS power guidelines below the 25 nm technology node should be revised if isothermal scaling of thin-body devices is desired.

E. Pop | R. Dutton | K. Goodson

[1] Seungmin Lee,et al. Heat transport in thin dielectric films , 1997 .

[2] J. Ziman,et al. In: Electrons and Phonons , 1961 .

[3] Kenneth E. Goodson,et al. Phonon scattering in silicon films with thickness of order 100 nm , 1999 .

[4] G. Pei,et al. FinFET design considerations based on 3-D simulation and analytical modeling , 2002 .

[5] Kenneth E. Goodson,et al. Sub-Continuum Simulations of Heat Conduction in Silicon-on-Insulator Transistors , 1999, Heat Transfer: Volume 3.

[6] Chenming Hu,et al. Direct-tunneling gate leakage current in double-gate and ultrathin body MOSFETs , 2002 .

[7] T. Yamane,et al. Measurement of thermal conductivity of silicon dioxide thin films using a 3ω method , 2002 .

[8] R. Pohl,et al. Thermal boundary resistance , 1989 .

[9] Kenneth E. Goodson,et al. Measurement and modeling of self-heating in SOI nMOSFET's , 1994 .

[10] Ying Zhang,et al. Extension and source/drain design for high-performance FinFET devices , 2003 .

[11] M. Asheghi,et al. Thermal conduction in doped single-crystal silicon films , 2002 .

[12] M. Lundstrom,et al. Essential physics of carrier transport in nanoscale MOSFETs , 2002 .