Hydrogen-induced disproportionation of Zr2Co

Masanori Hara; Ryo Hayakawa; Kuniaki Watanabe

doi:10.2320/matertrans1989.41.1146

Hydrogen-induced disproportionation of Zr₂Co

Masanori Hara, Ryo Hayakawa, Kuniaki Watanabe

Hydrogen Isotope Research Center, Organization for Promotion of Research

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

10 Scopus citations

Abstract

The kinetics of hydrogen-induced disproportionation of Zr₂Co was studied by the conventional constant volume method in a temperature range of 773 to 873 K. It was found that Zr₂Co disproportionated as 2Zr₂Co+3H₂→3ZrH₂+ZrCo₂ through a two-step mechanism as 1) Zr₂Co+H₂→ZrH₂+ZrCo and 2) 2ZrCo+H₂→ZrH₂+ZrCo₂. The first step was very fast and completed within only 100 s at 773 K. The rate, however, decreased with increases in temperature. The apparent rate constant for the first step disproportionation was determined to be k = 2.0×10^-2exp[15.0×10³ (J/mol)/RT], where the kinetics could be explained by nucleation and one-dimensional growth model. The kinetics of the second step disproportionation could be explained by nucleation and three-dimensional growth model.

Original language	English
Pages (from-to)	1146-1149
Number of pages	4
Journal	Unknown Journal
Volume	41
Issue number	9
DOIs	https://doi.org/10.2320/matertrans1989.41.1146
State	Published - 2000/09

ASJC Scopus subject areas

General Engineering

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10.2320/matertrans1989.41.1146

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@article{3c77265b60104693b218a9e7611e2f59,

title = "Hydrogen-induced disproportionation of Zr2Co",

abstract = "The kinetics of hydrogen-induced disproportionation of Zr2Co was studied by the conventional constant volume method in a temperature range of 773 to 873 K. It was found that Zr2Co disproportionated as 2Zr2Co+3H2→3ZrH2+ZrCo2 through a two-step mechanism as 1) Zr2Co+H2→ZrH2+ZrCo and 2) 2ZrCo+H2→ZrH2+ZrCo2. The first step was very fast and completed within only 100 s at 773 K. The rate, however, decreased with increases in temperature. The apparent rate constant for the first step disproportionation was determined to be k = 2.0×10-2exp[15.0×103 (J/mol)/RT], where the kinetics could be explained by nucleation and one-dimensional growth model. The kinetics of the second step disproportionation could be explained by nucleation and three-dimensional growth model.",

author = "Masanori Hara and Ryo Hayakawa and Kuniaki Watanabe",

year = "2000",

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doi = "10.2320/matertrans1989.41.1146",

language = "英語",

volume = "41",

pages = "1146--1149",

journal = "Unknown Journal",

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TY - JOUR

T1 - Hydrogen-induced disproportionation of Zr2Co

AU - Hara, Masanori

AU - Hayakawa, Ryo

AU - Watanabe, Kuniaki

PY - 2000/9

Y1 - 2000/9

N2 - The kinetics of hydrogen-induced disproportionation of Zr2Co was studied by the conventional constant volume method in a temperature range of 773 to 873 K. It was found that Zr2Co disproportionated as 2Zr2Co+3H2→3ZrH2+ZrCo2 through a two-step mechanism as 1) Zr2Co+H2→ZrH2+ZrCo and 2) 2ZrCo+H2→ZrH2+ZrCo2. The first step was very fast and completed within only 100 s at 773 K. The rate, however, decreased with increases in temperature. The apparent rate constant for the first step disproportionation was determined to be k = 2.0×10-2exp[15.0×103 (J/mol)/RT], where the kinetics could be explained by nucleation and one-dimensional growth model. The kinetics of the second step disproportionation could be explained by nucleation and three-dimensional growth model.

AB - The kinetics of hydrogen-induced disproportionation of Zr2Co was studied by the conventional constant volume method in a temperature range of 773 to 873 K. It was found that Zr2Co disproportionated as 2Zr2Co+3H2→3ZrH2+ZrCo2 through a two-step mechanism as 1) Zr2Co+H2→ZrH2+ZrCo and 2) 2ZrCo+H2→ZrH2+ZrCo2. The first step was very fast and completed within only 100 s at 773 K. The rate, however, decreased with increases in temperature. The apparent rate constant for the first step disproportionation was determined to be k = 2.0×10-2exp[15.0×103 (J/mol)/RT], where the kinetics could be explained by nucleation and one-dimensional growth model. The kinetics of the second step disproportionation could be explained by nucleation and three-dimensional growth model.

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