CHINESE ACADEMY OF SCIENCES

A research group led by Professor Zhuge Fei at the Ningbo Institute of Materials Technology and Engineering (NIMTE) of the Chinese Academy of Sciences (CAS) developed an all-optically controlled (AOC) analog memristor, the memconductance of which can be reversibly tuned by varying only the wavelength of the controlling light. The study was published in Advanced Functional Materials.

The all-optically controlled memristor developed for optoelectronic neuromorphic computing [IMAGE: NINGBO INSTITUTE OF MATERIALS TECHNOLOGY AND ENGINEERING, CHINESE ACADEMY OF SCIENCES]

As the next generation of artificial intelligence (AI), neuromorphic computing (NC) emulates the neural structure and operation of the human brain at the physical level, and thus can efficiently perform multiple advanced computing tasks such as learning, recognition and cognition.

Memristors are promising candidates for NC thanks to the feasibility of high-density 3D integration and low energy consumption. The emerging optoelectronic memristors are particularly competitive as they combine the advantages of both photonics and electronics. However, the reversible tuning of memconductance depends highly on electric excitation, which severely limits the development and application of optoelectronic NC.

To address this issue, researchers at NIMTE proposed a bilayered oxide AOC memristor based on the relatively mature semiconductor material InGaZnO and a memconductance tuning mechanism of light-induced electron trapping and detrapping.

Traditional electrical memristors require strong electrical stimuli to tune their memconductance, leading to high power consumption, a large amount of Joule heat, microstructural change triggered by the Joule heat, and even high crosstalk in memristor crossbars.

The developed AOC memristor by contrast does not involve microstructure changes, and can operate upon weak light irradiation with light power density of only 20 μW cm-2, which provides a new approach to overcoming the instability of the memristor.

Specifically, the AOC memristor can serve as an excellent synaptic emulator and thus mimic spike-timing-dependent plasticity (STDP) which is an important learning rule in the brain, indicating its potential applications in AOC spiking neural networks for high-efficiency optoelectronic NC.

Moreover, compared to purely optical computing, the optoelectronic computing using the team’s AOC memristor showed higher practical feasibility on account of its simple structure and fabrication process.

The study may shed light on the in-depth research and practical application of optoelectronic NC, and thus promote development of a new generation of AI.

For more information, please contact

Prof. Zhuge Fei

E-mail: zhugefei@nimte.ac.cn

Ningbo Institute of Materials Technology and Engineering,

Chinese Academy of Sciences

Source: Ningbo Institute of Materials Technology and Engineering,

Chinese Academy of Sciences

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