Microbubble formation from ionic vacancies in copper anodic dissolution under a high magnetic field

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

doi:10.5796/electrochemistry.83.549

Microbubble formation from ionic vacancies in copper anodic dissolution under a high magnetic field

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

^*Corresponding author for this work

Research Organization for Nano & Life Innovation

Research output: Contribution to journal › Article › peer-review

12 Citations (Scopus)

Abstract

Ionic vacancies created in copper anodic dissolution has been firstly observed by the conversion to microbubbles using both of cyclotron effect and pinch effect under a vertical magnetic field; in a circulating solution induced by Lorentz force, ionic vacancies collide with each other, changing to nanobubbles. Then, the circulation of the nanobubbles with solution makes further collisions, yielding microbubbles. Based on this result, the lifetimes of ionic vacancy formed in copper electrodeposition were finally determined.

Original language	English
Pages (from-to)	549-553
Number of pages	5
Journal	Electrochemistry
Volume	83
Issue number	7
DOIs	https://doi.org/10.5796/electrochemistry.83.549
Publication status	Published - 2015

Keywords

Anodic dissolution
Ionic vacancy
Magnetic field
Nanobubble

ASJC Scopus subject areas

Electrochemistry

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10.5796/electrochemistry.83.549

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title = "Microbubble formation from ionic vacancies in copper anodic dissolution under a high magnetic field",

abstract = "Ionic vacancies created in copper anodic dissolution has been firstly observed by the conversion to microbubbles using both of cyclotron effect and pinch effect under a vertical magnetic field; in a circulating solution induced by Lorentz force, ionic vacancies collide with each other, changing to nanobubbles. Then, the circulation of the nanobubbles with solution makes further collisions, yielding microbubbles. Based on this result, the lifetimes of ionic vacancy formed in copper electrodeposition were finally determined.",

keywords = "Anodic dissolution, Ionic vacancy, Magnetic field, Nanobubble",

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T1 - Microbubble formation from ionic vacancies in copper anodic dissolution under a high magnetic field

AU - Oshikiri, Yoshinobu

AU - Aogaki, Ryoichi

AU - Miura, Makoto

AU - Sugiyama, Atsushi

AU - Morimoto, Ryoichi

AU - Miura, Miki

AU - Mogi, Iwao

AU - Yamauchi, Yusuke

PY - 2015

Y1 - 2015

N2 - Ionic vacancies created in copper anodic dissolution has been firstly observed by the conversion to microbubbles using both of cyclotron effect and pinch effect under a vertical magnetic field; in a circulating solution induced by Lorentz force, ionic vacancies collide with each other, changing to nanobubbles. Then, the circulation of the nanobubbles with solution makes further collisions, yielding microbubbles. Based on this result, the lifetimes of ionic vacancy formed in copper electrodeposition were finally determined.

AB - Ionic vacancies created in copper anodic dissolution has been firstly observed by the conversion to microbubbles using both of cyclotron effect and pinch effect under a vertical magnetic field; in a circulating solution induced by Lorentz force, ionic vacancies collide with each other, changing to nanobubbles. Then, the circulation of the nanobubbles with solution makes further collisions, yielding microbubbles. Based on this result, the lifetimes of ionic vacancy formed in copper electrodeposition were finally determined.

KW - Anodic dissolution

KW - Ionic vacancy

KW - Magnetic field

KW - Nanobubble

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JO - Electrochemistry

JF - Electrochemistry

IS - 7

ER -

Microbubble formation from ionic vacancies in copper anodic dissolution under a high magnetic field

Abstract

Keywords

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