Forksheet Field-Effect Transistors for Area Scaling and Gate-Drain Capacitance Reduction in Nanosheet-based CMOS Technologies

被引:0
|
作者
Mertens, H. [1 ]
Horiguchi, N. [1 ]
机构
[1] IMEC, Leuven, Belgium
来源
8TH IEEE ELECTRON DEVICES TECHNOLOGY & MANUFACTURING CONFERENCE, EDTM 2024 | 2024年
关键词
D O I
10.1109/EDTM58488.2024.10511640
中图分类号
T [工业技术];
学科分类号
08 ;
摘要
Nanosheet-based field-effect transistors with dielectric walls between adjacent devices, referred to as forksheet transistors, can improve CMOS scaling by means of (1) space reduction between transistors and (2) gate-drain capacitance reduction. We demonstrate forksheet device fabrication, including self-aligned gate cut formation for lateral channel-channel spaces as small as 12nm. In addition, we discuss pros and cons of different forksheet wall configurations. Dielectric walls positioned at standard cell outer bounds instead of inner bounds have the benefit that wall width scalability is independent of N-P patterning requirements. Source-drain cut patterning is an option to address process-induced wall loss between source-drains.
引用
收藏
页码:756 / 758
页数:3
相关论文
共 50 条
  • [1] Forksheet Field-Effect Transistors for Area Scaling and Gate-Drain Capacitance Reduction in Nanosheet-based CMOS Technologies
    Mertens, H.
    Horiguchi, N.
    IEEE Electron Devices Technology and Manufacturing Conference: Strengthening the Globalization in Semiconductors, EDTM 2024, 2024,
  • [2] Multiple Gate Field-Effect Transistors for Future CMOS Technologies
    Subramanian, Vaidyanathan
    IETE TECHNICAL REVIEW, 2010, 27 (06) : 446 - 454
  • [3] Tunnel field-effect transistor without gate-drain overlap
    Verhulst, Anne S.
    Vandenberghe, William G.
    Maex, Karen
    Groeseneken, Guido
    APPLIED PHYSICS LETTERS, 2007, 91 (05)
  • [4] Physical limitations in scaling field-effect transistors and technologies beyond CMOS
    Willander, M
    Fu, Y
    PHYSICS OF SEMICONDUCTOR DEVICES, VOLS 1 AND 2, 1998, 3316 : 986 - 993
  • [5] Trap characterization by gate-drain conductance and capacitance dispersion studies of an AlGaN/GaN heterostructure field-effect transistor
    Miller, EJ
    Dang, XZ
    Wieder, HH
    Asbeck, PM
    Yu, ET
    Sullivan, GJ
    Redwing, JM
    JOURNAL OF APPLIED PHYSICS, 2000, 87 (11) : 8070 - 8073
  • [6] Modelling of the Gate Capacitance in the Double Nanowire based Field-Effect Transistors
    Liu, Fengyuan
    Dahiya, Ravinder
    PROCEEDINGS OF THE 2021 IEEE INTERNATIONAL CONFERENCE ON FLEXIBLE AND PRINTABLE SENSORS AND SYSTEMS (FLEPS), 2021,
  • [7] Analytical Parasitic Resistance and Capacitance Models for Nanosheet Field-Effect Transistors
    Suk, JunHa
    Kim, YoHan
    Do, JungHo
    Kim, GaRoom
    Baek, SangHoon
    Kye, JongWook
    Kim, SoYoung
    IEEE TRANSACTIONS ON ELECTRON DEVICES, 2023, 70 (06) : 2941 - 2946
  • [8] Gate-Controlled Metal to Insulator Transition in Black Phosphorus Nanosheet-Based Field Effect Transistors
    Ali, Nasir
    Lee, Myeongjin
    Ali, Fida
    Shin, Hoseong
    Ngo, Tien Dat
    Watanabe, Kenji
    Taniguchi, Takashi
    Oh, Byungdu
    Yoo, Won Jong
    ACS APPLIED NANO MATERIALS, 2022, 5 (12) : 18376 - 18384
  • [9] Influence of the Thickness of the Barrier Layer in Nanoheterostructures and the Gate-Drain Capacitance on the Microwave and Noise Parameters of Field-Effect AlGaN/GaN HEMT
    S. V. Mikhaylovich
    Yu.V. Fedorov
    Radiophysics and Quantum Electronics, 2016, 59 : 153 - 160
  • [10] Influence of the Thickness of the Barrier Layer in Nanoheterostructures and the Gate-Drain Capacitance on the Microwave and Noise Parameters of Field-Effect AlGaN/GaN HEMT
    Mikhaylovich, S. V.
    Fedorov, Yu V.
    RADIOPHYSICS AND QUANTUM ELECTRONICS, 2016, 59 (02) : 153 - 160
12345