Solid electrochemical micromachining using a tungsten microelectrode coated n with a polymer electrolyte

Kai Kamada; Masaaki Tokutomi; Miki Inada; Naoya Enomoto; Junichi Hojo

doi:10.2109/jcersj2.115.672

Solid electrochemical micromachining using a tungsten microelectrode coated n with a polymer electrolyte

Kai Kamada, Masaaki Tokutomi, Miki Inada, Naoya Enomoto, Junichi Hojo

Center of Advanced Instrumental Analysis

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

4 Citations (Scopus)

Abstract

Electrochemical micromachining of a metal plate was performed using a solid polymer electrolyte. The fundamental electrolysis system was composed of a metal plate (anode) | polymer electrolyte | tungsten needle (cathode), where the contact diameter of the metal | polymer interface was extremely small (a few μm). The metal substrate was electrochemically oxidized and then M ⁿ⁺ ions migrated to the polymer electrolyte. As a result of the continuous application of a dc voltage to the cell, finer-resolution micromachining (∼10μm) was achieved under room-temperature operation as compared with our previous results obtained using a Na-β″-Al ₂O₃ solid electrolyte. Furthermore, the present technique was applicable to many different kinds of metal substrates.

Original language	English
Pages (from-to)	672-677
Number of pages	6
Journal	Journal of the Ceramic Society of Japan
Volume	115
Issue number	1346
DOIs	https://doi.org/10.2109/jcersj2.115.672
Publication status	Published - Oct 2007

All Science Journal Classification (ASJC) codes

Ceramics and Composites
Chemistry(all)
Condensed Matter Physics
Materials Chemistry

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10.2109/jcersj2.115.672

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abstract = "Electrochemical micromachining of a metal plate was performed using a solid polymer electrolyte. The fundamental electrolysis system was composed of a metal plate (anode) | polymer electrolyte | tungsten needle (cathode), where the contact diameter of the metal | polymer interface was extremely small (a few μm). The metal substrate was electrochemically oxidized and then M n+ ions migrated to the polymer electrolyte. As a result of the continuous application of a dc voltage to the cell, finer-resolution micromachining (∼10μm) was achieved under room-temperature operation as compared with our previous results obtained using a Na-β″-Al 2O3 solid electrolyte. Furthermore, the present technique was applicable to many different kinds of metal substrates.",

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T1 - Solid electrochemical micromachining using a tungsten microelectrode coated n with a polymer electrolyte

AU - Kamada, Kai

AU - Tokutomi, Masaaki

AU - Inada, Miki

AU - Enomoto, Naoya

AU - Hojo, Junichi

PY - 2007/10

Y1 - 2007/10

N2 - Electrochemical micromachining of a metal plate was performed using a solid polymer electrolyte. The fundamental electrolysis system was composed of a metal plate (anode) | polymer electrolyte | tungsten needle (cathode), where the contact diameter of the metal | polymer interface was extremely small (a few μm). The metal substrate was electrochemically oxidized and then M n+ ions migrated to the polymer electrolyte. As a result of the continuous application of a dc voltage to the cell, finer-resolution micromachining (∼10μm) was achieved under room-temperature operation as compared with our previous results obtained using a Na-β″-Al 2O3 solid electrolyte. Furthermore, the present technique was applicable to many different kinds of metal substrates.

AB - Electrochemical micromachining of a metal plate was performed using a solid polymer electrolyte. The fundamental electrolysis system was composed of a metal plate (anode) | polymer electrolyte | tungsten needle (cathode), where the contact diameter of the metal | polymer interface was extremely small (a few μm). The metal substrate was electrochemically oxidized and then M n+ ions migrated to the polymer electrolyte. As a result of the continuous application of a dc voltage to the cell, finer-resolution micromachining (∼10μm) was achieved under room-temperature operation as compared with our previous results obtained using a Na-β″-Al 2O3 solid electrolyte. Furthermore, the present technique was applicable to many different kinds of metal substrates.

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Solid electrochemical micromachining using a tungsten microelectrode coated n with a polymer electrolyte

Abstract

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