Phase Transitions and Thermal Expansion Behavior in AuCu Alloy

Thermal expansion behavior in a stoichiometric AuCu alloy was investigated from a point of view of a phase transition. Thermal expansion measurement was carried out from room temperature to 873 K at various heating and cooling rate. The crystal structures and the phase transitions were analyzed by X...

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Veröffentlicht in:	Journal of the Japan Institute of Metals and Materials 2008, Vol.72(5), pp.311-316
Hauptverfasser:	Anraku, Teruo, Sakaihara, Iwao, Hoshikawa, Takeshi, Taniwaki, Masafumi
Format:	Artikel
Sprache:	jpn
Schlagworte:	activation energy Cooling rate differential scanning calorimetry gold copper alloy Heating Intermetallic compounds Order-disorder transformations order-disorder transition Phase transitions Quenching Room temperature Self diffusion Thermal expansion thermal expansion curve X-ray diffractmetry
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container_title	Journal of the Japan Institute of Metals and Materials
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creator	Anraku, Teruo Sakaihara, Iwao Hoshikawa, Takeshi Taniwaki, Masafumi
description	Thermal expansion behavior in a stoichiometric AuCu alloy was investigated from a point of view of a phase transition. Thermal expansion measurement was carried out from room temperature to 873 K at various heating and cooling rate. The crystal structures and the phase transitions were analyzed by X-ray diffractmetry and differential scanning calorimetry, respectively. The structure of the casted alloy was a disordered face-centered cubic and changed to a face-centered tetragonal structure or mixed structure of fcc and AuCu I after thermal expansion measurement. In the thermal expansion curves, break points were corresponded to order-disorder transition. During the heating process, three break points corresponding to three different ordering stages were observed. The activation energy for each stage was obtained using Kissinger method. It was considered that first and second stages are ascribed to the migration of excess vacancies induced by quenching, and third stage is predominated by self-diffusion.
doi_str_mv	10.2320/jinstmet.72.311
format	Article
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Thermal expansion measurement was carried out from room temperature to 873 K at various heating and cooling rate. The crystal structures and the phase transitions were analyzed by X-ray diffractmetry and differential scanning calorimetry, respectively. The structure of the casted alloy was a disordered face-centered cubic and changed to a face-centered tetragonal structure or mixed structure of fcc and AuCu I after thermal expansion measurement. In the thermal expansion curves, break points were corresponded to order-disorder transition. During the heating process, three break points corresponding to three different ordering stages were observed. The activation energy for each stage was obtained using Kissinger method. 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Japan Inst. Metals and Materials</addtitle><description>Thermal expansion behavior in a stoichiometric AuCu alloy was investigated from a point of view of a phase transition. Thermal expansion measurement was carried out from room temperature to 873 K at various heating and cooling rate. The crystal structures and the phase transitions were analyzed by X-ray diffractmetry and differential scanning calorimetry, respectively. The structure of the casted alloy was a disordered face-centered cubic and changed to a face-centered tetragonal structure or mixed structure of fcc and AuCu I after thermal expansion measurement. In the thermal expansion curves, break points were corresponded to order-disorder transition. During the heating process, three break points corresponding to three different ordering stages were observed. The activation energy for each stage was obtained using Kissinger method. 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Japan Inst. Metals and Materials</addtitle><date>2008-05-01</date><risdate>2008</risdate><volume>72</volume><issue>5</issue><spage>311</spage><epage>316</epage><pages>311-316</pages><issn>0021-4876</issn><eissn>1880-6880</eissn><abstract>Thermal expansion behavior in a stoichiometric AuCu alloy was investigated from a point of view of a phase transition. Thermal expansion measurement was carried out from room temperature to 873 K at various heating and cooling rate. The crystal structures and the phase transitions were analyzed by X-ray diffractmetry and differential scanning calorimetry, respectively. The structure of the casted alloy was a disordered face-centered cubic and changed to a face-centered tetragonal structure or mixed structure of fcc and AuCu I after thermal expansion measurement. In the thermal expansion curves, break points were corresponded to order-disorder transition. During the heating process, three break points corresponding to three different ordering stages were observed. The activation energy for each stage was obtained using Kissinger method. It was considered that first and second stages are ascribed to the migration of excess vacancies induced by quenching, and third stage is predominated by self-diffusion.</abstract><cop>Sendai</cop><pub>The Japan Institute of Metals and Materials</pub><doi>10.2320/jinstmet.72.311</doi><tpages>6</tpages><oa>free_for_read</oa></addata></record>
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subjects	activation energy Cooling rate differential scanning calorimetry gold copper alloy Heating Intermetallic compounds Order-disorder transformations order-disorder transition Phase transitions Quenching Room temperature Self diffusion Thermal expansion thermal expansion curve X-ray diffractmetry
title	Phase Transitions and Thermal Expansion Behavior in AuCu Alloy
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