Author
Listed:
- Baowei Yuan
(Fudan University
Fudan University)
- Zhibo Chen
(Fudan University)
- Yingxin Chen
(Fudan University)
- Chengjie Tang
(Fudan University)
- Weiao Chen
(Fudan University)
- Zengguang Cheng
(Fudan University)
- Chunsong Zhao
(LTD.)
- Zhaozhao Hou
(LTD.)
- Qiang Zhang
(LTD.)
- Weizhuo Gan
(LTD.)
- Jiacheng Gao
(LTD.)
- Jiale Wang
(LTD.)
- Jeffrey Xu
(LTD.)
- Guangxi Hu
(Fudan University)
- Zhenhua Wu
(Chinese Academy of Sciences)
- Kun Luo
(Chinese Academy of Sciences)
- Mingyan Luo
(Fudan University)
- Yuanbo Zhang
(Fudan University)
- Zengxing Zhang
(Fudan University)
- Shisheng Xiong
(Fudan University)
- Chunxiao Cong
(Fudan University)
- Wenzhong Bao
(Fudan University)
- Shunli Ma
(Fudan University)
- Jing Wan
(Fudan University)
- Peng Zhou
(Fudan University)
- Ye Lu
(Fudan University)
Abstract
Impact ionization effect has been demonstrated in transistors to enable sub-60 mV dec−1 subthreshold swing. However, traditionally, impact ionization in silicon devices requires a high operation voltage due to limited electrical field near the device drain, contradicting the low energy operation purpose. Here, we report a vertical subthreshold swing device composed of a graphene/silicon heterojunction drain and a silicon channel. This structure creates a low voltage avalanche impact ionization phenomenon and leads to steep switching of the silicon-based device. Experimental measurements reveal a small average subthreshold swing of 16 µV dec−1 over 6 decades of drain current and nearly hysteresis-free, and the operating voltage at which a vertical subthreshold swing occurs can be as low as 0.4 V at room temperature. Furthermore, a complementary silicon-based logic inverter is experimentally demonstrated to reach a voltage gain of 311 at a supply voltage of 2 V.
Suggested Citation
Baowei Yuan & Zhibo Chen & Yingxin Chen & Chengjie Tang & Weiao Chen & Zengguang Cheng & Chunsong Zhao & Zhaozhao Hou & Qiang Zhang & Weizhuo Gan & Jiacheng Gao & Jiale Wang & Jeffrey Xu & Guangxi Hu , 2024.
"High drain field impact ionization transistors as ideal switches,"
Nature Communications, Nature, vol. 15(1), pages 1-8, December.
Handle:
RePEc:nat:natcom:v:15:y:2024:i:1:d:10.1038_s41467-024-53337-8
DOI: 10.1038/s41467-024-53337-8
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