肖特基势垒
肖特基二极管
范德瓦尔斯力
整流器(神经网络)
单层
材料科学
半导体
费米能级
凝聚态物理
兴奋剂
金属半导体结
理想(伦理)
光电子学
电接点
纳米技术
物理
二极管
量子力学
分子
计算机科学
电子
人工神经网络
哲学
随机神经网络
认识论
机器学习
循环神经网络
作者
Xiankun Zhang,Baishan Liu,Gao Li,Huihui Yu,Xiaozhi Liu,Junli Du,Jiankun Xiao,Yihe Liu,Lin Gu,Qingliang Liao,Zhuo Kang,Zheng Zhang,Yue Zhang
标识
DOI:10.1038/s41467-021-21861-6
摘要
Abstract The applications of any two-dimensional (2D) semiconductor devices cannot bypass the control of metal-semiconductor interfaces, which can be severely affected by complex Fermi pinning effects and defect states. Here, we report a near-ideal rectifier in the all-2D Schottky junctions composed of the 2D metal 1 T′-MoTe 2 and the semiconducting monolayer MoS 2 . We show that the van der Waals integration of the two 2D materials can efficiently address the severe Fermi pinning effect generated by conventional metals, leading to increased Schottky barrier height. Furthermore, by healing original atom-vacancies and reducing the intrinsic defect doping in MoS 2 , the Schottky barrier width can be effectively enlarged by 59%. The 1 T′-MoTe 2 /healed-MoS 2 rectifier exhibits a near-unity ideality factor of ~1.6, a rectifying ratio of >5 × 10 5 , and high external quantum efficiency exceeding 20%. Finally, we generalize the barrier optimization strategy to other Schottky junctions, defining an alternative solution to enhance the performance of 2D-material-based electronic devices.
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