Gate tunable giant anisotropic resistance in ultra-thin GaTe

被引:0
作者
Hanwen Wang
Mao-Lin Chen
Mengjian Zhu
Yaning Wang
Baojuan Dong
Xingdan Sun
Xiaorong Zhang
Shimin Cao
Xiaoxi Li
Jianqi Huang
Lei Zhang
Weilai Liu
Dongming Sun
Yu Ye
Kepeng Song
Jianjian Wang
Yu Han
Teng Yang
Huaihong Guo
Chengbing Qin
Liantuan Xiao
Jing Zhang
Jianhao Chen
Zheng Han
Zhidong Zhang
机构
[1] Chinese Academy of Sciences,Shenyang National Laboratory for Materials Science, Institute of Metal Research
[2] University of Science and Technology of China,School of Material Science and Engineering
[3] National University of Defense Technology,College of Advanced Interdisciplinary Studies
[4] Shanxi University,State Key Laboratory of Quantum Optics and Quantum Optics Devices, Institute of Laser Spectroscopy
[5] Shanxi University,Collaborative Innovation Center of Extreme Optics
[6] Peking University,International Center for Quantum Materials, School of Physics
[7] Collaborative Innovation Center of Quantum Matter,State Key Lab for Mesoscopic Physics and School of Physics
[8] Peking University,Advanced Membranes and Porous Materials Center, Physical Science and Engineering Division
[9] King Abdullah University of Science and Technology,Multi
[10] Chongqing University,scale Porous Materials Center, Institute of Advanced Interdisciplinary Studies
[11] Liaoning Shihua University,College of Sciences
[12] Institute of Opto-Electronics,State Key Laboratory of Quantum Optics and Quantum Optics Devices
[13] Shanxi University,undefined
来源
Nature Communications | / 10卷
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摘要
Anisotropy in crystals arises from different lattice periodicity along different crystallographic directions, and is usually more pronounced in two dimensional (2D) materials. Indeed, in the emerging 2D materials, electrical anisotropy has been one of the recent research focuses. However, key understandings of the in-plane anisotropic resistance in low-symmetry 2D materials, as well as demonstrations of model devices taking advantage of it, have proven difficult. Here, we show that, in few-layered semiconducting GaTe, electrical conductivity anisotropy between x and y directions of the 2D crystal can be gate tuned from several fold to over 103. This effect is further demonstrated to yield an anisotropic non-volatile memory behavior in ultra-thin GaTe, when equipped with an architecture of van der Waals floating gate. Our findings of gate-tunable giant anisotropic resistance effect pave the way for potential applications in nanoelectronics such as multifunctional directional memories in the 2D limit.
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