Title :
Sub-60-nm quasi-planar FinFETs fabricated using a simplified process
Author :
Lindert, N. ; Chang, Ly-Yu ; Yang-Kyu Choi ; Anderson, E.H. ; Wen-Chin Lee ; Tsu-Jae King ; Bokor, J. ; Chenming Hu
Author_Institution :
Dept. of Electr. Eng. & Comput. Sci., California Univ., Berkeley, CA, USA
Abstract :
N-channel double-gate metal-oxide-semiconductor field-effect transistor (MOSFET) FinFETs with gate and fin dimensions as small as 30 nm have been fabricated using a new, simplified process. Short channel effects are effectively suppressed when the Si fin width is less than two-thirds of the gate length. The drive current for typical devices is found to be above 500 μA/μm (or 1 mA/μm, depending on the definition of the width of the double-gate device) for V/sub g/-VT=V/sub d/=1 V. The electrical gate oxide thickness in these devices is 21 /spl Aring/, determined from the first FinFET capacitance-versus-voltage characteristics obtained to date. These results indicate that the FinFET is a promising structure for the future manufacturing of integrated circuits with sub-60-nm feature size, and that double-gate MOSFETs can meet international technology roadmap for semiconductors performance specifications without aggressive scaling of the gate-oxide thickness.
Keywords :
Ge-Si alloys; MOS integrated circuits; MOSFET; semiconductor technology; silicon; 1 V; 21 A; 30 to 60 nm; C-V characteristics; Si; Si fin width; SiGe; SiGe gate; capacitance-voltage characteristics; double-gate MOSFET; electrical gate oxide thickness; field-effect transistor; fin dimensions; gate dimensions; integrated circuits; n-channel MOSFET; quasi-planar FinFETs; short channel effects suppression; simplified process; Capacitance-voltage characteristics; Double-gate FETs; Etching; Fabrication; FinFETs; MOSFET circuits; Optical films; Resists; Scanning electron microscopy; Silicon;
Journal_Title :
Electron Device Letters, IEEE
