A new approach for in-situ studying the phase transition of paramagnetic materials: High-temperature Faraday Balance

Cui Ping Zhang; X. Chaud; E. Beaugnon; Hai Tao Cao; Lian Zhou

A new approach for in-situ studying the phase transition of paramagnetic materials: High-temperature Faraday Balance

Cui Ping Zhang, X. Chaud, E. Beaugnon, Hai Tao Cao, Lian Zhou

School of Materials Sience and Engineering

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

Abstract

Based on the principle of the susceptibility transformation in the phase transition of paramagnetic material, the high-temperature Faraday Balance can observe the dynamic process in the phase transition of material. We utilize it measuring the susceptibility variation of Ag₂O and CuO at high temperature. It reveals the dynamic decomposing process in the melting of Ag₂O and the solidification of Ag, as well as the decomposition and halfway synthesis reaction of CuO. By the two examples, we introduce this new approach for studying the phase transition of paramagnetic materials-high-temperature Faraday Balance. This method provides a reliable experimental data for the materials' fabricating process.

Original language	English
Pages (from-to)	23-27
Number of pages	5
Journal	Cailiao Kexue yu Gongyi/Material Science and Technology
Volume	19
Issue number	2
State	Published - Apr 2011

Keywords

AgO
Crystallization phase transition
CuO
High-temperature Faraday Balance
Susceptibility

Cite this

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abstract = "Based on the principle of the susceptibility transformation in the phase transition of paramagnetic material, the high-temperature Faraday Balance can observe the dynamic process in the phase transition of material. We utilize it measuring the susceptibility variation of Ag2O and CuO at high temperature. It reveals the dynamic decomposing process in the melting of Ag2O and the solidification of Ag, as well as the decomposition and halfway synthesis reaction of CuO. By the two examples, we introduce this new approach for studying the phase transition of paramagnetic materials-high-temperature Faraday Balance. This method provides a reliable experimental data for the materials' fabricating process.",

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AU - Chaud, X.

AU - Beaugnon, E.

AU - Cao, Hai Tao

AU - Zhou, Lian

PY - 2011/4

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N2 - Based on the principle of the susceptibility transformation in the phase transition of paramagnetic material, the high-temperature Faraday Balance can observe the dynamic process in the phase transition of material. We utilize it measuring the susceptibility variation of Ag2O and CuO at high temperature. It reveals the dynamic decomposing process in the melting of Ag2O and the solidification of Ag, as well as the decomposition and halfway synthesis reaction of CuO. By the two examples, we introduce this new approach for studying the phase transition of paramagnetic materials-high-temperature Faraday Balance. This method provides a reliable experimental data for the materials' fabricating process.

AB - Based on the principle of the susceptibility transformation in the phase transition of paramagnetic material, the high-temperature Faraday Balance can observe the dynamic process in the phase transition of material. We utilize it measuring the susceptibility variation of Ag2O and CuO at high temperature. It reveals the dynamic decomposing process in the melting of Ag2O and the solidification of Ag, as well as the decomposition and halfway synthesis reaction of CuO. By the two examples, we introduce this new approach for studying the phase transition of paramagnetic materials-high-temperature Faraday Balance. This method provides a reliable experimental data for the materials' fabricating process.

KW - AgO

KW - Crystallization phase transition

KW - CuO

KW - High-temperature Faraday Balance

KW - Susceptibility

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JO - Cailiao Kexue yu Gongyi/Material Science and Technology

JF - Cailiao Kexue yu Gongyi/Material Science and Technology

IS - 2

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A new approach for in-situ studying the phase transition of paramagnetic materials: High-temperature Faraday Balance

Abstract

Keywords

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