Synthesis and Characteristics of CuO Immobilized in Porous Alumina for the Removal of Hydrogen Generated by the Fission 99Mo Production

Myunggoo Kang; Hyun Jung; Kang Hyuk Choi; Jun Sig Lee

doi:10.1002/bkcs.11880

Synthesis and Characteristics of CuO Immobilized in Porous Alumina for the Removal of Hydrogen Generated by the Fission ⁹⁹Mo Production

Myunggoo Kang, Hyun Jung, Kang Hyuk Choi, Jun Sig Lee

Department of Chemistry

Korea Atomic Energy Research Institute

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

1 Scopus citations

Abstract

Fission ⁹⁹Mo, which is one of the fission products from the irradiated ²³⁵U target, has been mainly produced through the dissolving procedure in an alkali solution. However, this approach has problems with the explosion of the generated hydrogen gas. In this research, we designed the porous alumina ball immobilized in CuO (CuO-PAB) for the hydrogen removal. The CuO-PAB was prepared by calcining the commercial PAB absorbed Cu ion. The nano-sized CuO particles are distributed evenly in the porous network of PAB without any significant aggregation. Also, the wall of the PAB's pore channel hinders the aggregation and growth of CuO particles during the hydrogen removal process. These structural benefits show that the CuO-PAB is superior to bulk-CuO at the capacity and reaction rate of hydrogen conversion. Furthermore, these performances were durable in the recycling experiments.

Original language	English
Pages (from-to)	1117-1122
Number of pages	6
Journal	Bulletin of the Korean Chemical Society
Volume	40
Issue number	11
DOIs	https://doi.org/10.1002/bkcs.11880
State	Published - 1 Nov 2019

Keywords

Copper oxide
Fission Mo
Hydrogen removal
Immobilization
Porous structure

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10.1002/bkcs.11880

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title = "Synthesis and Characteristics of CuO Immobilized in Porous Alumina for the Removal of Hydrogen Generated by the Fission 99Mo Production",

abstract = "Fission 99Mo, which is one of the fission products from the irradiated 235U target, has been mainly produced through the dissolving procedure in an alkali solution. However, this approach has problems with the explosion of the generated hydrogen gas. In this research, we designed the porous alumina ball immobilized in CuO (CuO-PAB) for the hydrogen removal. The CuO-PAB was prepared by calcining the commercial PAB absorbed Cu ion. The nano-sized CuO particles are distributed evenly in the porous network of PAB without any significant aggregation. Also, the wall of the PAB's pore channel hinders the aggregation and growth of CuO particles during the hydrogen removal process. These structural benefits show that the CuO-PAB is superior to bulk-CuO at the capacity and reaction rate of hydrogen conversion. Furthermore, these performances were durable in the recycling experiments.",

keywords = "Copper oxide, Fission Mo, Hydrogen removal, Immobilization, Porous structure",

author = "Myunggoo Kang and Hyun Jung and Choi, {Kang Hyuk} and Lee, {Jun Sig}",

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doi = "10.1002/bkcs.11880",

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T1 - Synthesis and Characteristics of CuO Immobilized in Porous Alumina for the Removal of Hydrogen Generated by the Fission 99Mo Production

AU - Kang, Myunggoo

AU - Jung, Hyun

AU - Choi, Kang Hyuk

AU - Lee, Jun Sig

PY - 2019/11/1

Y1 - 2019/11/1

N2 - Fission 99Mo, which is one of the fission products from the irradiated 235U target, has been mainly produced through the dissolving procedure in an alkali solution. However, this approach has problems with the explosion of the generated hydrogen gas. In this research, we designed the porous alumina ball immobilized in CuO (CuO-PAB) for the hydrogen removal. The CuO-PAB was prepared by calcining the commercial PAB absorbed Cu ion. The nano-sized CuO particles are distributed evenly in the porous network of PAB without any significant aggregation. Also, the wall of the PAB's pore channel hinders the aggregation and growth of CuO particles during the hydrogen removal process. These structural benefits show that the CuO-PAB is superior to bulk-CuO at the capacity and reaction rate of hydrogen conversion. Furthermore, these performances were durable in the recycling experiments.

AB - Fission 99Mo, which is one of the fission products from the irradiated 235U target, has been mainly produced through the dissolving procedure in an alkali solution. However, this approach has problems with the explosion of the generated hydrogen gas. In this research, we designed the porous alumina ball immobilized in CuO (CuO-PAB) for the hydrogen removal. The CuO-PAB was prepared by calcining the commercial PAB absorbed Cu ion. The nano-sized CuO particles are distributed evenly in the porous network of PAB without any significant aggregation. Also, the wall of the PAB's pore channel hinders the aggregation and growth of CuO particles during the hydrogen removal process. These structural benefits show that the CuO-PAB is superior to bulk-CuO at the capacity and reaction rate of hydrogen conversion. Furthermore, these performances were durable in the recycling experiments.

KW - Copper oxide

KW - Fission Mo

KW - Hydrogen removal

KW - Immobilization

KW - Porous structure

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JF - Bulletin of the Korean Chemical Society

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ER -

Synthesis and Characteristics of CuO Immobilized in Porous Alumina for the Removal of Hydrogen Generated by the Fission ⁹⁹Mo Production

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Keywords

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