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2010

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Development of Novel Transistor with Combined Logic and Memory Functions with Power Consumption Reduced to One-Millionth that of Conventional Devices

Road to the Development of an Instant-on PC

National Institute for Materials Science
Japan Science and Technology Agency
Osaka University
University of Tokyo

A group headed by Dr. Tsuyoshi Hasegawa, a Principal Investigator at the International Center for Materials Nanoarchitectonics, National Institute for Materials Science, in joint research with Prof. Takuji Ogawa of the Graduate School of Science, Osaka University, and a research group under Prof. Shu Yamaguchi of the Graduate School of Engineering, The University of Tokyo, succeeded in the development of a novel transistor.

Abstract

  1. A group headed by Dr. Tsuyoshi Hasegawa, a Principal Investigator at the International Center for Materials Nanoarchitectonics (MANA; Director-General: Masakazu Aono), National Institute for Materials Science (President: Sukekatsu Ushioda), in joint research with a research group under Prof. Takuji Ogawa of the Graduate School of Science, Osaka University, and a research group under Prof. Shu Yamaguchi of the Graduate School of Engineering, The University of Tokyo, succeeded in the development of a novel transistor, the “atom transistor,” which performs both logic and memory functions while reducing power consumption to 1 x 10-6 that of the conventional devices. Logic elements which are capable of retaining their state (i.e., memory) will be indispensible for the development of instant-on personal computers (PC) and other electronic equipment. The development in this work is expected to accelerate the realization of these devices.
  2. In contrast to conventional transistors, which control the movement of electrons in a semiconductor, the newly-developed “atom transistor” operates by transferring a very small amount of metal atoms in an insulator. By using an insulator, which has higher resistance than a semiconductor, as the base material, and realizing on/off states by transfer of a tiny amount metal atoms in this material, the new device achieves a high on/off ratio on the same level as conventional semiconductor transistors with extremely low power consumption. Furthermore, it was found that the “atom transistor” also operates as a memory element which retains states by control of the operating voltage range.
  3. As non-volatile logic circuits, which reconfigure circuits corresponding to computational results, are able to retain their state even when the power supply is turned off, high expectations are placed on the developed device as a new type of computer circuit for realizing PCs with zero starting time. Conventionally, one “logic element with memory” was formed by combining a logic element (transistor) and a memory element (memory). However, with the conventional devices, the power consumption required for memory is extremely high, and low power consumption, in which memory power requirements are greatly reduced, had been considered necessary for practical application. The “atom transistor” developed in this research reduces the power consumption required for memory to 1/1,000,000 that of the conventional technology. In addition, because it possesses both logic and memory functions, it is expected to contribute to the realization of neural computing systems.
  4. This research was carried out as part of the research topic “Development of Atom Transistor” (Research Representative: Tsuyoshi Hasegawa) in the research area “Research of Innovative Material and Process for Creation of Next-generation Electronics Devices” (Research Supervisor, Dr. Hisatsune Watanabe, President & CEO, Semiconductor Leading Edge Technologies, Inc.), Core Research of Evolutional Science & Technology, Team-based Basic Research (CREST) of the Japan Science and Technology Agency (JST). These results were published online by the scientific journal “Applied Physics Express (APEX)” on December 24, 2010.

Fig. 4 :Principles of logic element operation and memory element operation.(a) When a positive voltage is applied to the gate electrode, metal atoms are supplied to the insulator from the gate electrode. (b) When the concentration of metal atoms in the vicinity of the source/drain electrodes exceeds a critical value, the insulator changes to a conductive state. (c) When an even higher voltage is applied, the metal atoms form a cluster. (d) It is necessary to apply a negative voltage in order to dissolve the cluster.

Fig. 4 :Principles of logic element operation and memory element operation.(a) When a positive voltage is applied to the gate electrode, metal atoms are supplied to the insulator from the gate electrode. (b) When the concentration of metal atoms in the vicinity of the source/drain electrodes exceeds a critical value, the insulator changes to a conductive state. (c) When an even higher voltage is applied, the metal atoms form a cluster. (d) It is necessary to apply a negative voltage in order to dissolve the cluster.



APEX-published paper

Title of paper: Volatile/Nonvolatile Dual-Functional Atom Transistor
Authors: Tsuyoshi Hasegawa, Yaomi Itoh, Hirofumi Tanaka, Takami Hino, Tohru Tsuruoka, Kazuya Terabe, Hisao Miyazaki, Kazuhito Tsukagoshi, Takuji Ogawa, Shu Yamaguchi, and Masakazu Aono.


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