Research and development on membrane IS process for hydrogen production using solar heat
Myagmarjav, O. ; 岩月 仁 ; 田中 伸幸 ; 野口 弘喜 ; 上地 優; 井岡 郁夫 ; 久保 真治 ; 野村 幹弘*; 八巻 徹也*; 澤田 真一*; 都留 稔了*; 金指 正言*; Yu, X.*; 町田 正人*; 石原 達己*; 阿部川 弘明*; 水野 雅彦*; 田口 智将*; 細野 恭生*; 栗木 良郎*; 猪俣 誠*; 宮嶋 圭太*; 稲垣 嘉之; 坂場 成昭
Myagmarjav, O.; Iwatsuki, Jin; Tanaka, Nobuyuki; Noguchi, Hiroki; Kamiji, Yu; Ioka, Ikuo; Kubo, Shinji; Nomura, Mikihiro*; Yamaki, Tetsuya*; Sawada, Shinichi*; Tsuru, Toshinori*; Kanezashi, Masakoto*; Yu, X.*; Machida, Masato*; Ishihara, Tatsumi*; Abekawa, Hiroaki*; Mizuno, Masahiko*; Taguchi, Tomoyuki*; Hosono, Yasuo*; Kuriki, Yoshiro*; Inomata, Makoto*; Miyajima, Keita*; Inagaki, Yoshiyuki; Sakaba, Nariaki
Thermochemical hydrogen production has attracted considerable interest as a clean energy solution to address the challenges of climate change and environmental sustainability. The thermochemical water-splitting iodine-sulfur (IS) process uses heat from nuclear or solar power and thus is a promising next-generation thermochemical hydrogen production method that is independent of fossil fuels and can provide energy security. This paper presents the current state of research and development of the IS process based on membrane techniques using solar energy at a medium temperature of 600C. Membrane design strategies have the most potential for making the IS process using solar energy highly efficient and economical and are illustrated here in detail. Three aspects of membrane design proposed herein for the IS process have led to a considerable improvement of the total thermal efficiency of the process: membrane reactors, membranes, and reaction catalysts. Experimental studies in the applications of these membrane design techniques to the Bunsen reaction, sulfuric acid decomposition, and hydrogen iodide decomposition are discussed.