Title :
Sub-50 nm P-channel FinFET
Author :
Huang, Xuejue ; Lee, Wen-Chin ; Kuo, Charles ; Hisamoto, Digh ; Chang, Leland ; Kedzierski, Jakub ; Anderson, Erik ; Takeuchi, Hideki ; Choi, Yang-Kyu ; Asano, Kazuya ; Subramanian, Vivek ; King, Tsu-Jae ; Bokor, Jeffrey ; Hu, Chenming
Author_Institution :
Dept. of Electr. Eng. & Comput. Sci., California Univ., Berkeley, CA, USA
fDate :
5/1/2001 12:00:00 AM
Abstract :
High-performance PMOSFETs with sub-50-nm gate-length are reported. A self-aligned double-gate MOSFET structure (FinFET) is used to suppress the short-channel effects. This vertical double-gate SOI MOSFET features: 1) a transistor channel which is formed on the vertical surfaces of an ultrathin Si fin and controlled by gate electrodes formed on both sides of the fin; 2) two gates which are self-aligned to each other and to the source/drain (S/D) regions; 3) raised S/D regions; and 4) a short (50 nm) Si fin to maintain quasi-planar topology for ease of fabrication. The 45-nm gate-length p-channel FinFET showed an Idsat of 820 μA/μm at Vds=Vgs=1.2 V and T ox=2.5 mm. Devices showed good performance down to a gate-length of 18 nm. Excellent short-channel behavior was observed. The fin thickness (corresponding to twice the body thickness) is found to be critical for suppressing the short-channel effects. Simulations indicate that the FinFET structure can work down to 10 nm gate length. Thus, the FinFET is a very promising structure for scaling CMOS beyond 50 nm
Keywords :
MOSFET; semiconductor device measurement; silicon-on-insulator; 1.2 V; 18 to 45 nm; 50 nm; P-channel FinFET; SOI MOSFET; Si; fin thickness; gate electrodes; quasi-planar topology; raised S/D regions; self-aligned double-gate MOSFET structure; short-channel behavior; short-channel effects; transistor channel; vertical surfaces; Electrodes; Fabrication; FinFETs; Germanium silicon alloys; Laboratories; MOS devices; MOSFET circuits; Silicon germanium; Surface resistance; Topology;
Journal_Title :
Electron Devices, IEEE Transactions on
