Title :
Nanoscale CMOS spacer FinFET for the terabit era
Author :
Choi, Yang-Kyu ; King, Tsu-Jae ; Hu, Chenming
Author_Institution :
Dept. of Electr. Eng. & Comput. Sci., California Univ., Berkeley, CA, USA
Abstract :
A spacer lithography process technology, which uses a sacrificial layer and spacer layer formed by chemical vapor deposition (CVD), has been developed. It has been applied to make a sub-40-nm Si-fin structure for a double-gate FinFET with conventional dry etching for the first time. The minimum-sized features are defined not by the photolithography but by the CVD film thickness. Therefore, this spacer lithography technology yields better critical dimension uniformity than conventional optical or e-beam lithography and defines smaller features beyond the limit of current lithography technology. It also provides a doubling of feature density for a given lithography pitch, which increases current by a factor of two. To demonstrate this spacer lithography technology, Si-fin structures have been patterned for planar double-gate CMOS FinFET devices.
Keywords :
CMOS integrated circuits; chemical mechanical polishing; chemical vapour deposition; integrated circuit technology; lithography; nanotechnology; silicon-on-insulator; 40 nm; CMP; CVD film thickness; CVD formed spacer layer; SOI; Si; chemical mechanical polishing; chemical vapor deposition; critical dimension uniformity; device fabrication; double-gate FinFET; dry etching; gate planarization; nanoscale Si-fin structure; planar double-gate CMOS devices; sacrificial layer; spacer etch; spacer lithography process technology; CMOS technology; Chemical technology; Etching; FinFETs; Lithography; Optical films; Oxidation; Silicon on insulator technology; Space technology; Thermal stresses;
Journal_Title :
Electron Device Letters, IEEE
