• DocumentCode
    3128585
  • Title

    FinFET scaling to 10 nm gate length

  • Author

    Yu, El ; Chang, Leland ; Ahmed, Shibly ; Wang, Haihong ; Bell, Scott ; Yang, Chih-Yuh ; Tabery, Cyrus ; Ho, Chau ; Xiang, Qi ; King, Tsu-Jae ; Bokor, Jeffrey ; Hu, Chenming ; Lin, Ming-Ren ; Kyser, David

  • Author_Institution
    Strategic Technol., Adv. Micro Devices Inc., Sunnyvale, CA, USA
  • fYear
    2002
  • fDate
    8-11 Dec. 2002
  • Firstpage
    251
  • Lastpage
    254
  • Abstract
    While the selection of new "backbone" device structure in the era of post-planar CMOS is open to a few candidates, FinFET and its variants show great potential in scalability and manufacturability for nanoscale CMOS. In this paper we report the design, fabrication, performance, and integration issues of double-gate FinFETs with the physical gate length being aggressively shrunk down to 10 nm and the fin width down to 12 nm. These MOSFETs are believed to be the smallest double-gate transistors ever fabricated. Excellent short-channel performance is observed in devices with a wide range of gate lengths (10/spl sim/105 nm). The observed short-channel behavior outperforms any reported single-gate silicon MOSFETs. Due to the [110] channel crystal orientation, hole mobility in the fabricated p-channel FinFET exceeds greatly that in a traditional planar MOSFET. At 105 nm gate length, the p-channel FinFET shows a record-high transconductance of 633 /spl mu/S//spl mu/m at a V/sub dd/ of 1.2 V. Working CMOS FinFET inverters are also demonstrated.
  • Keywords
    CMOS integrated circuits; MOSFET; integrated circuit technology; nanoelectronics; silicon; 1.2 V; 10 to 105 nm; 6.33E5 muS/mm; CMOS FinFET inverters; DIBL; FinFET scaling; [110] channel crystal orientation; double-gate FinFET; double-gate transistors; fabrication; integration issues; nanoscale CMOS; p-channel FinFET; scaling performance; short-channel performance; transconductance; Fabrication; FinFETs; Inverters; MOSFETs; Manufacturing; Nanoscale devices; Scalability; Silicon; Spine; Transconductance;
  • fLanguage
    English
  • Publisher
    ieee
  • Conference_Titel
    Electron Devices Meeting, 2002. IEDM '02. International
  • Conference_Location
    San Francisco, CA, USA
  • Print_ISBN
    0-7803-7462-2
  • Type

    conf

  • DOI
    10.1109/IEDM.2002.1175825
  • Filename
    1175825