Title :
Lateral Strain Profile as Key Technology Booster for All-Silicon Tunnel FETs
Author :
Boucart, Kathy ; Riess, Walter Riess ; Ionescu, Adrian Mihai
Author_Institution :
Swiss Fed. Inst. of Technol. (EPFL), Lausanne, Switzerland
fDate :
6/1/2009 12:00:00 AM
Abstract :
In this letter, we propose a lateral asymmetric strain profile in a silicon nanowire or ultrathin silicon film as a key technology booster for the performance of all-silicon tunnel FETs. We demonstrate by simulation that a Gaussian tensile-strain profile with a maximum placed at the source side of a nanowire tunnel FET with a 50-nm channel length provides an optimized solution for a low-standby-power switch. This leads to the following: (1) ultralow I off (more than three decades lower than in the case of a device on uniformly strained silicon); (2) boosting of I on (more than one decade higher compared to a silicon reference); and (3) an average subthreshold swing S avg of 48 mV/dec at room temperature. Furthermore, the inherent finite drain threshold voltage of the tunnel FET, which could be a disadvantage for logic design with tunnel FETs, is exponentially reduced with the strain-induced bandgap shrinkage at the source side.
Keywords :
elemental semiconductors; field effect transistors; nanowires; semiconductor thin films; silicon; tunnel transistors; Gaussian tensile-strain profile; Si; all-silicon tunnel FET; average subthreshold swing; inherent finite drain threshold voltage; lateral asymmetric strain profile; logic design; low-standby-power switch; silicon nanowire; size 50 nm; strain-induced bandgap shrinkage; temperature 293 K to 298 K; ultrathin silicon film; Bandgap engineering; Tunnel FET; band-to-band tunneling; silicon nanowires; strain engineering; surface tunneling transistor (STT);
Journal_Title :
Electron Device Letters, IEEE
DOI :
10.1109/LED.2009.2018127
