Scientific Reports (Jan 2021)

Amorphous metal oxide semiconductor thin film, analog memristor, and autonomous local learning for neuromorphic systems

  • Mutsumi Kimura,
  • Ryo Sumida,
  • Ayata Kurasaki,
  • Takahito Imai,
  • Yuta Takishita,
  • Yasuhiko Nakashima

DOI
https://doi.org/10.1038/s41598-020-79806-w
Journal volume & issue
Vol. 11, no. 1
pp. 1 – 7

Abstract

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Abstract Artificial intelligence is a promising concept in modern and future societies. Presently, software programs are used but with a bulky computer size and large power consumption. Conversely, hardware systems named neuromorphic systems are suggested, with a compact computer size and low power consumption. An important factor is the number of processing elements that can be integrated. In the present study, three decisive technologies are proposed: (1) amorphous metal oxide semiconductor thin films, one of which, Ga–Sn–O (GTO) thin film, is used. GTO thin film does not contain rare metals and can be deposited by a simple process at room temperature. Here, oxygen-poor and oxygen-rich layers are stacked. GTO memristors are formed at cross points in a crossbar array; (2) analog memristor, in which, continuous and infinite information can be memorized in a single device. Here, the electrical conductance gradually changes when a voltage is applied to the GTO memristor. This is the effect of the drift and diffusion of the oxygen vacancies (Vo); and (3) autonomous local learning, i.e., extra control circuits are not required since a single device autonomously modifies its own electrical characteristic. Finally, a neuromorphic system is assembled using the abovementioned three technologies. The function of the letter recognition is confirmed, which can be regarded as an associative memory, a typical artificial intelligence application.