Title :
Modeling self-heating effects in 10nm channel length nanowire transistors
Author :
Hossain, A. ; Vasileska, D. ; Goodnick, S.M. ; Raleva, Katerina
Author_Institution :
Intel Corp., Chandler, AZ, USA
Abstract :
In this work we focus on investigation of self-heating effect in 10 nm wide, 7 nm thick and 10 nm long channel of a silicon nanowire transistor, shown in Fig. 1. The difference between this structure and the previously investigated 2D fully depleted SOI transistors is that the SiO2 is now all around the structure, not just at the top and the bottom. Because SiO2 has very low thermal conductivity, and the nanowire itself has low thermal conductivity (because of phonon boundary scattering in the rectangular cross section), it was expected that self heating effects are more pronounced in the nanowire transistor when compared to the same channel length fully-depleted SOI device. Indeed, our extrapolation of the results at hand for fully depleted SOI devices with 10 nm channel length were expected to be on the order of 4.4%.
Keywords :
elemental semiconductors; nanoelectronics; nanowires; semiconductor device models; silicon; silicon compounds; silicon-on-insulator; thermal conductivity; transistors; 2D full depleted SOI transistors; Si; SiO2; channel length nanowire transistors; self-heating effect modelling; silicon nanowire transistor; size 10 nm; size 7 nm; thermal conductivity; Degradation; Heating; Logic gates; Metals; Nanoscale devices; Phonons; Transistors;
Conference_Titel :
Silicon Nanoelectronics Workshop (SNW), 2010
Conference_Location :
Honolulu, HI
Print_ISBN :
978-1-4244-7727-2
Electronic_ISBN :
978-1-4244-7726-5
DOI :
10.1109/SNW.2010.5562566
