Title: Oxidation-boosted charge trapping in ultra-sensitive van der Waals materials for artificial synaptic features
Authors: Yang, Feng-Shou
Li, Mengjiao
Lee, Mu-Pai
Ho, I-Ying
Chen, Jiann-Yeu
Ling, Haifeng
Li, Yuanzhe
Chang, Jen-Kuei
Yang, Shih-Hsien
Chang, Yuan-Ming
Lee, Ko-Chun
Chou, Yi-Chia
Ho, Ching-Hwa
Li, Wenwu
Lien, Chen-Hsin
Lin, Yen-Fu
電子物理學系
Department of Electrophysics
Issue Date: 12-Jun-2020
Abstract: Exploitation of the oxidation behaviour in an environmentally sensitive semiconductor is significant to modulate its electronic properties and develop unique applications. Here, we demonstrate a native oxidation-inspired InSe field-effect transistor as an artificial synapse in device level that benefits from the boosted charge trapping under ambient conditions. A thin InOx layer is confirmed under the InSe channel, which can serve as an effective charge trapping layer for information storage. The dynamic characteristic measurement is further performed to reveal the corresponding uniform charge trapping and releasing process, which coincides with its surface-effect-governed carrier fluctuations. As a result, the oxide-decorated InSe device exhibits nonvolatile memory characteristics with flexible programming/erasing operations. Furthermore, an InSe-based artificial synapse is implemented to emulate the essential synaptic functions. The pattern recognition capability of the designed artificial neural network is believed to provide an excellent paradigm for ultra-sensitive van der Waals materials to develop electric-modulated neuromorphic computation architectures. Developing efficient memory and artificial synaptic systems based on environmentally sensitive van der Waals materials remains a challenge. Here, the authors present a native oxidation-inspired InSe field-effect transistor that benefits from a boosted charge trapping behavior under ambient conditions.
URI: http://dx.doi.org/10.1038/s41467-020-16766-9
http://hdl.handle.net/11536/154963
ISSN: 2041-1723
DOI: 10.1038/s41467-020-16766-9
Journal: NATURE COMMUNICATIONS
Volume: 11
Issue: 1
Begin Page: 0
End Page: 0
Appears in Collections:Articles