IMCE

Institute for Materials Chemistry and Engineering, Kyushu University

九州大学
先導物質化学研究所

LAST UPDATE 2025/06/02

  • 研究者氏名
    Researcher Name

    宮脇仁 Jin MIYAWAKI
    准教授 Associate Professor

  • 所属
    Affiliation

    九州大学 先導物質化学研究所
    Institute for Materials Chemistry and Engineering, Kyushu University

    先端素子材料部門
    Division of Advanced Device Materials

  • 研究キーワード
    Research Keywords

    炭素材料
    細孔
    吸着
    表面
    Carbon materials
    Pore
    Adsorption
    Surface
研究テーマ
Research Subject
高機能性多孔性炭素材料の創成と応用
Development of high-performance porous carbon materials for energy saving and environmental protection

研究の背景 Background of the Research

物質の貯蔵・分離に欠く事ができない多孔性炭素材料の機能は、表面および細孔構造に大きく依存しています。細孔発達のメカニズムを理解することで表面および細孔構造をより精密に制御することが可能となり、省エネルギーや環境保全などの用途に合わせた高機能・新機能を有する多孔性炭素材料を創製できるようになります。

Functions of porous carbon materials, which are indispensable for material storage and separation, strongly depend on surface and pore structures. Understanding of pore development mechanism enables to finely tune the surface and pore characteristics of the porous carbon materials, and then a fabrication of the porous carbon materials having high and new functionalities optimized for various applications of energy saving and environmental protection fields becomes possible.

研究の目標 Research Objective

エネルギーおよび環境問題の解決に貢献できる高性能多孔性炭素材の開発を目指しています。機能発現の鍵である細孔構造発達メカニズムを解明し、それに基づいた新規調製法及び材料開発、そして吸着式ヒートポンプや大気浄化、エネルギー貯蔵などへの応用研究を行っています。

Research is aimed at a development of high-performance porous carbon materials to solve energy and environmental problems. Mechanism of pore development is tried to be elucidated, and new porous carbon materials are being fabricated by newly developed production methods based on the revealed mechanism. Applications of the prepared porous carbon materials to various purposes, such as adsorption heat pump, air purification, and energy storage, are also investigated.

研究図Figures

Fig.1. Proposed model of pore structures of activated carbons based on the micro-domain concept. Fig.2. 2H solid-state NMR spectra of CH3CH2OD-adsorbed activated carbons having different contents of surface functionalities (above). Schematic of trapping of ethanol molecules by surface functionalities (below). Fig.3. SEM image of newly developed spherical activated carbon (above). Ethanol adsorption/desorption isotherms of newly developed and commercial activated carbons at 303 K

論文発表 / Publications

J. Power Sources, 646, 237202 (2025). J. Am. Chem. Soc., 146, 34401 (2024). Acc. Mater. Surf. Res., 9, 46 (2024). Carbon Reports, 3, 18 (2024). Carbon, 216, 118570 (2024). Carbon Reports, 2, 179 (2023). RSC Adv., 12, 2558 (2022). Carbon, 183, 735 (2021). Carbon, 170, 380 (2020). AIP Conf. Proc., 2097, 020002 (2019). Carbon, 114, 98 (2017).

研究者連絡先 / HP