绝缘体上的硅
材料科学
MOSFET
光电子学
硅
蒙特卡罗方法
CMOS芯片
电子工程
纳米尺度
电气工程
纳米技术
电压
晶体管
工程类
统计
数学
作者
C. Fiegna,Yang Yang,E. Sangiorgi,A.G. O’Neill
标识
DOI:10.1109/ted.2007.911354
摘要
This paper discusses self-heating (SHE) effects in silicon-on-insulator (SOI) CMOS technology and applies device simulation to analyze the impact of thermal effects on the operation of nanoscale SOI n-MOSFETs. A 2-D drift-diffusion electrothermal simulation, using an electron transport model calibrated against Monte Carlo simulations at various temperatures, is employed in the analysis. We report the effects of devicestructure parameters, such as SOI layer thickness, buried-oxide (BOX) thickness, source/drain (S/D) extension length, and thickness of the elevated S/D region, on the SHE of nanoscale MOSFETs. The SHE effects become significant due to the adoption of thin silicon layers and to the low thermal conductivity of the BOX, leading to the rise of large temperature under nominal operation conditions for high-performance digital circuits. The ac performance of SOI MOSFETs is influenced as well, and in particular, a severe degradation of the cutoff frequency of very short MOSFETs is predicted by numerical electrothermal device simulations. Although the effects of SHE on device performance are found to be somewhat modest and might be mitigated through device design, they may result in a degradation of the long-term reliability.
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