理工学部 教員紹介

murakami tomoyuki

  (村上 朝之)

Profile Information

Affiliation
Professor, Faculty of Science and Technology Department of Science and Technology , Seikei University
Degree
Doctor of Engineering

J-GLOBAL ID
200901029179161369
researchmap Member ID
1000321721

External link

Papers

 91
  • Osamu Sakai, Toshifusa Karasaki, Tsuyohito Ito, Tomoyuki Murakami, Manabu Tanaka, Makoto Kambara, Satoshi Hirayama
    PLOS ONE, 19(4) e0300842-e0300842, Apr 10, 2024  Peer-reviewed
    Maze-solving is a classical mathematical task, and is recently analogously achieved using various eccentric media and devices, such as living tissues, chemotaxis, and memristors. Plasma generated in a labyrinth of narrow channels can also play a role as a route finder to the exit. In this study, we experimentally observe the function of maze-route findings in a plasma system based on a mixed discharge scheme of direct-current (DC) volume mode and alternative-current (AC) surface dielectric-barrier discharge, and computationally generalize this function in a reinforcement-learning model. In our plasma system, we install two electrodes at the entry and the exit in a square lattice configuration of narrow channels whose cross section is 1×1 mm2 with the total length around ten centimeters. Visible emissions in low-pressure Ar gas are observed after plasma ignition, and the plasma starting from a given entry location reaches the exit as the discharge voltage increases, whose route converging level is quantified by Shannon entropy. A similar short-path route is reproduced in a reinforcement-learning model in which electric potentials through the discharge voltage is replaced by rewards with positive and negative sign or polarity. The model is not rigorous numerical representation of plasma simulation, but it shares common points with the experiments along with a rough sketch of underlying processes (charges in experiments and rewards in modelling). This finding indicates that a plasma-channel network works in an analog computing function similar to a reinforcement-learning algorithm slightly modified in this study.
  • Katsuya Iuchi, Mami Fukasawa, Tomoyuki Murakami, Hisashi Hisatomi
    Cell Biochemistry and Function, 41(6) 687-695, Jun 15, 2023  Peer-reviewed
  • Satoru Kawaguchi, Tomoyuki Murakami
    Japanese Journal of Applied Physics, 61(8) 086002-086002, Aug 1, 2022  Peer-reviewedLast author
  • Osamu Sakai, Satoru Kawaguchi, Tomoyuki Murakami
    Japanese Journal of Applied Physics, 61(7) 070101-070101, Jul 1, 2022  Peer-reviewedInvitedLast author
  • Toshiro Kaneko, Hiromitsu Kato, Hideaki Yamada, Muneaki Yamamoto, Tomoko Yoshida, Pankaj Attri, Kazunori Koga, Tomoyuki Murakami, Kazuyuki Kuchitsu, Sugihiro Ando, Yasuhiro Nishikawa, Kentaro Tomita, Ryo Ono, Tsuyohito Ito, Atsushi M. Ito, Koji Eriguchi, Tomohiro Nozaki, Takayoshi Tsutsumi, Kenji Ishikawa
    Japanese Journal of Applied Physics, 61(SA) SA0805, Jan 1, 2022  Peer-reviewed
    <title>Abstract</title> Nitrogen is a very common element, comprising approximately 78% of Earth’s atmosphere, and is an important component of various electronic devices while also being essential for life. However, it is challenging to directly utilize dinitrogen because of the highly stable triple bond in this molecule. The present review examines the use of non-equilibrium plasmas to generate controlled electron impacts as a means of generating reactive nitrogen species (RNS) with high internal energy values and extremely short lifetimes. These species include ground state nitrogen atoms, excited nitrogen atoms, etc. RNS can subsequently react with oxygen and/or hydrogen to generate new highly reactive compounds and can also be used to control various cell functions and create new functional materials. Herein, plasma-processing methods intended to provide RNS serving as short-lived precursors for a range of applications are examined in detail.

Misc.

 7

Books and Other Publications

 14

Presentations

 202

Teaching Experience

 5

Research Projects

 33

Academic Activities

 1

Other

 5
  • 2019 - 2021
    成蹊学園サステナビリティ教育研究センターにおけるプロジェクト. マクロ・ミクロ両面での環境計測に基づき, 学園全体の省エネルギー化に文理融合, 教職協働, 師弟同行の体制で取り組む.
  • 2017 - 2017
    Shining light on cold atmospheric plasmas and their interaction with liquids. In collaboration with University of Oxford and Queen's University Belfast (UK). Supported by Engineering and Physical Sciences Research Council (UK).
  • 2015 - 2015
    In collaboration with Weslyan University (USA) and Queen's University Belfast (UK) on modeling the evolution of plasma (an assembly of ions and electrons) created by injecting energy into water. This project focuses on water in both the vapor phase and as a liquid.
  • 2011 - 2011
    COST Actions are a flexible, fast, effective and efficient networking instrument for researchers, engineers and scholars to cooperate and coordinate nationally funded research activities. COST Actions allow European researchers to jointly develop their own ideas in any science and technology field.