{"id":9093,"date":"2023-01-05T17:24:09","date_gmt":"2023-01-05T08:24:09","guid":{"rendered":"https:\/\/c-mng.cwh.hokudai.ac.jp\/LMSE.eng\/Root\/?page_id=9093"},"modified":"2024-12-09T14:00:46","modified_gmt":"2024-12-09T05:00:46","slug":"achievements2023","status":"publish","type":"page","link":"https:\/\/c-mng.cwh.hokudai.ac.jp\/LMSE.eng\/Root\/achievements2023.html","title":{"rendered":"\u7814\u7a76\u6210\u679c"},"content":{"rendered":"

2024<\/h1>\n

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    \n
  1. Deuterium Isotope Separation using LiCl\u2013KCl\u2013LiH\u2013LiD Molten Salt
    \nToranosuke Nago (D2)<\/strong><\/span>, Yutaro Norikawa, Kenji Harada, Mikito Ueda, Hisayoshi Matsushima<\/span>, Toshiyuki Nohira
    \nECS Advances. 3<\/b>\u00a0042502<\/em><\/a><\/li>\n
  2. Al Electroplating on Etched CFRP Surfaces in AlCl3-EmImCl Ionic Liquids
    \nNaoki Kishi (M2)<\/strong><\/span>, Hisayoshi Matsushima, Mikito Ueda<\/span>
    \n
    ECS Transactions.<\/em>\u00a0114<\/b>, 65, 2024<\/a><\/li>\n
  3. Correlation between Electrolyte Concentration and Lithium Morphology during Lithium Bis(fluorosulfonyl)amide\u2013Tetraglyme Electrolyte Deposition\u2013Dissolution Reactions
    \nGo Kamesui (D2)<\/strong><\/span>, Kei Nishikawa, Mikito Ueda, Hisayoshi Matsushima<\/span>
    \n
    Journal of the Electrochemical Society<\/em>. 171<\/strong>, 100507, 2024<\/a><\/li>\n
  4. High-Speed AFM Observation of Electrolytic Hydrogen Nanobubbles During Potential Scanning.
    \nRyuto Ohashi (M2)<\/strong><\/span>, Mikito Ueda,\u00a0Hisayoshi Matsushima<\/span>
    \n
    Electrochemical Science Advances.<\/em> e202400008, 2024<\/a><\/li>\n
  5. Elucidation of Mass Transport Phenomena in Highly Concentrated Electrolytes during Current Cycling Using In-Situ Interferometry and Finite Difference Method
    \nGo Kamesui (D2)<\/strong><\/span>, Kei Nishikawa, Mikito Ueda, Hisayoshi Matsushima<\/span>
    \n
    Journal of the Electrochemical Society<\/em>. 171<\/strong>, 040519, 2024<\/a><\/li>\n
  6. Deuterium enrichment by proton exchange membrane water electrolysis with electrolyte circulation
    \nIbiku Sato (M2)<\/strong><\/span>, Koichiro Furusawa<\/strong><\/span>, Mikito Ueda, Hisayoshi Matsushima<\/span>
    \n
    Fusion Engineering and Design<\/em>. 202<\/strong>, 114420, 2024<\/a><\/li>\n
  7. Application of membrane electrode assembly for water hydrogen isotope exchange
    \nKoichiro Furusawa (\u793eD3)<\/strong><\/span>, Toranosuke Nago (D1)<\/strong><\/span>, Mikito Ueda, Hisayoshi Matsushima<\/span>
    \n
    International Journal of Hydrogen Energy<\/em>. 50<\/strong>, 629-634, 2024<\/a><\/li>\n
  8. Anodic Dissolution Behavior of Al Alloys Containing Al6Fe or \u03b2-AlFeSi in EmImCl\u2013AlCl3 Electrolyte During Electrorefining
    \nJunji Nunomura(\u793eD3)<\/strong><\/span>, Hisayoshi Matsushima, Yoshikiho Kyo, Yoichi Kojima, Mikito Ueda<\/span>
    \n
    Journal of the Electrochemical Society<\/em>. 170<\/strong>, 122501, 2024<\/a><\/li>\n
  9. Arrangement of Al Ions between Ionic Liquid and Graphite Electrode Interface
    \nby AFM Force Curve Measurement
    \nAtsuki Tabo(M2)<\/strong><\/span>, Hisayoshi Matsushima, Takahiro Ohkubo, Kei Nishikawa,\u00a0 Mikito Ueda<\/span>
    \n
    Electrochemistry.<\/em> 92<\/strong> (4), 043011, 2024<\/a><\/li>\n
  10. Formation of Porous Gold Electrodeposits by Pulse Technique in AlCl\u2083\u2013NaCl\u2013KCl\u00a0 Molten Salt Containing AuCl
    \nMasaya Sugizaki(M2)<\/strong><\/span>, Hisayoshi Matsushima, Mikito Ueda<\/span>, Midori Kawamura
    \n
    Electrochemistry.<\/em> 92<\/strong> (4), 043005, 2024<\/a><\/li>\n<\/ol>\n

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