Origin of Nanobubbles Electrochemically Formed in a Magnetic Field: Ionic Vacancy Production in Electrode Reaction

Ryoichi Aogaki; Atsushi Sugiyama; Makoto Miura; Yoshinobu Oshikiri; Miki Miura; Ryoichi Morimoto; Satoshi Takagi; Iwao Mogi; Yusuke Yamauchi

doi:10.1038/srep28927

Origin of Nanobubbles Electrochemically Formed in a Magnetic Field: Ionic Vacancy Production in Electrode Reaction

Ryoichi Aogaki^*, Atsushi Sugiyama, Makoto Miura, Yoshinobu Oshikiri, Miki Miura, Ryoichi Morimoto, Satoshi Takagi, Iwao Mogi, Yusuke Yamauchi

^*この研究の対応する著者

ナノ・ライフ創新研究機構

研究成果: Article › 査読

11 被引用数 (Scopus)

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As a process complementing conventional electrode reactions, ionic vacancy production in electrode reaction was theoretically examined; whether reaction is anodic or cathodic, based on the momentum conservation by Newton's second law of motion, electron transfer necessarily leads to the emission of original embryo vacancies, and dielectric polarization endows to them the same electric charge as trans- ferred in the reaction. Then, the emitted embryo vacancies immediately receive the thermal relaxation of solution particles to develop steady-state vacancies. After the vacancy production, nanobubbles are created by the collision of the vacancies in a vertical magnetic field.

本文言語	English
論文番号	28927
ジャーナル	Scientific Reports
巻	6
DOI	https://doi.org/10.1038/srep28927
出版ステータス	Published - 2016 7月 5

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title = "Origin of Nanobubbles Electrochemically Formed in a Magnetic Field: Ionic Vacancy Production in Electrode Reaction",

abstract = "As a process complementing conventional electrode reactions, ionic vacancy production in electrode reaction was theoretically examined; whether reaction is anodic or cathodic, based on the momentum conservation by Newton's second law of motion, electron transfer necessarily leads to the emission of original embryo vacancies, and dielectric polarization endows to them the same electric charge as trans- ferred in the reaction. Then, the emitted embryo vacancies immediately receive the thermal relaxation of solution particles to develop steady-state vacancies. After the vacancy production, nanobubbles are created by the collision of the vacancies in a vertical magnetic field.",

author = "Ryoichi Aogaki and Atsushi Sugiyama and Makoto Miura and Yoshinobu Oshikiri and Miki Miura and Ryoichi Morimoto and Satoshi Takagi and Iwao Mogi and Yusuke Yamauchi",

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T1 - Origin of Nanobubbles Electrochemically Formed in a Magnetic Field

T2 - Ionic Vacancy Production in Electrode Reaction

AU - Aogaki, Ryoichi

AU - Sugiyama, Atsushi

AU - Miura, Makoto

AU - Oshikiri, Yoshinobu

AU - Miura, Miki

AU - Morimoto, Ryoichi

AU - Takagi, Satoshi

AU - Mogi, Iwao

AU - Yamauchi, Yusuke

PY - 2016/7/5

Y1 - 2016/7/5

N2 - As a process complementing conventional electrode reactions, ionic vacancy production in electrode reaction was theoretically examined; whether reaction is anodic or cathodic, based on the momentum conservation by Newton's second law of motion, electron transfer necessarily leads to the emission of original embryo vacancies, and dielectric polarization endows to them the same electric charge as trans- ferred in the reaction. Then, the emitted embryo vacancies immediately receive the thermal relaxation of solution particles to develop steady-state vacancies. After the vacancy production, nanobubbles are created by the collision of the vacancies in a vertical magnetic field.

AB - As a process complementing conventional electrode reactions, ionic vacancy production in electrode reaction was theoretically examined; whether reaction is anodic or cathodic, based on the momentum conservation by Newton's second law of motion, electron transfer necessarily leads to the emission of original embryo vacancies, and dielectric polarization endows to them the same electric charge as trans- ferred in the reaction. Then, the emitted embryo vacancies immediately receive the thermal relaxation of solution particles to develop steady-state vacancies. After the vacancy production, nanobubbles are created by the collision of the vacancies in a vertical magnetic field.

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Origin of Nanobubbles Electrochemically Formed in a Magnetic Field: Ionic Vacancy Production in Electrode Reaction

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