Chip, Volume. 3, Issue 3, 100098(2024)

Channel-bias-controlled reconfigurable silicon nanowire transistors via an asymmetric electrode contact strategy

Wentao Qian, Junzhuan Wang*, Jun Xu, and Linwei Yu**
Author Affiliations
  • School of Electronic Science and Engineering/National Laboratory of Solid-State Microstructures, Nanjing University, Nanjing 210093, China
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    Reconfigurable field-effect transistors (R-FETs) that can dynamically reconfigure the transistor polarity, from n-type to p-type channel or vice versa, represent a promising new approach to reduce the logic complexity and granularity of programmable electronics. Although R-FETs have been successfully demonstrated upon silicon nanowire (SiNW) channels, a pair of extra program gates is still needed to control the source/drain (S/D) contacts. In this work, we propose a rather simple single gate R-FET structure with an asymmetric S/D electrode contact, where the FET channel polarity can be altered by changing the sign of channel bias Vds. These R-FETs were fabricated upon an orderly array of planar SiNW channels, grown via in-plane solid-liquid-solid mechanism, and contacted by Ti/Al and Pt/Au at the S/D electrodes, respectively. Remarkably, this channel-bias-controlled R-FET strategy has been successfully testified and implemented upon both p-type-doped (with indium dopants) or n-type-doped (phosphorus) SiNW channels, whereas the R-FET prototypes demonstrate an impressive high Ion/off ratio of > 106 and a steep subthreshold swing of 79 mV/dec. These results indicate a rather simple, compact and generic enough R-FET strategy for the construction of a new generation of SiNW-based programmable and low-power electronics.

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    Wentao Qian, Junzhuan Wang, Jun Xu, Linwei Yu. Channel-bias-controlled reconfigurable silicon nanowire transistors via an asymmetric electrode contact strategy[J]. Chip, 2024, 3(3): 100098

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    Paper Information

    Category: Research Articles

    Received: Mar. 15, 2024

    Accepted: Jun. 3, 2024

    Published Online: Nov. 12, 2024

    The Author Email: Wang Junzhuan (wangjz@nju.edu.cn), Yu Linwei (yulinwei@nju.edu.cn)

    DOI:10.1016/j.chip.2024.100098

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