The suppression and recovery of martensitic transformation in a Ni-Co-Mn-In magnetic shape memory alloy
Identifieur interne : 000365 ( Chine/Analysis ); précédent : 000364; suivant : 000366The suppression and recovery of martensitic transformation in a Ni-Co-Mn-In magnetic shape memory alloy
Auteurs : RBID : Pascal:12-0105038Descripteurs français
- Pascal (Inist)
- Microstructure, Transformation martensitique, Surfusion, Microscopie électronique balayage, Précipitation, Dendrite, Calorimétrie différentielle balayage, Recuit, Alliage quaternaire, Alliage magnétique, Nickel alliage, Alliage mémoire forme, Cobalt alliage, Manganèse alliage, Indium alliage, Métal transition alliage.
English descriptors
- KwdEn :
- Annealing, Cobalt alloys, Dendrites, Differential scanning calorimetry, Indium alloys, Magnetic alloy, Manganese alloys, Martensitic transformations, Microstructure, Nickel alloys, Precipitation, Quaternary alloys, Scanning electron microscopy, Shape memory alloy, Supercooling, Transition element alloys.
Abstract
The intrinsic mechanism of the martensitic transformation (MT) suppression observed in Ni-Co-Mn-In alloys fabricated under non-equilibrium conditions still remains mysterious. Here, we used the undercooling technique to obtain a solidified microstructure in non-equilibrium state, subsequently leading to MT suppression even further cooling to 10 K. It was found that primary dendrite-like In-depleted precipitates occurred during solidification under a large undercooling. After a prolonged annealing, the MT interestingly appeared again due to the dissolution of the precipitates and the recovery of equilibrium chemical composition in the matrix.
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<record><TEI><teiHeader><fileDesc><titleStmt><title xml:lang="en" level="a">The suppression and recovery of martensitic transformation in a Ni-Co-Mn-In magnetic shape memory alloy</title><author><name sortKey="Wang, Z L" uniqKey="Wang Z">Z. L. Wang</name><affiliation wicri:level="1"><inist:fA14 i1="01"><s1>School of Materials Science and Engineering, Beijing Institute of Technology</s1><s2>Beijing 100081</s2><s3>CHN</s3><sZ>1 aut.</sZ><sZ>3 aut.</sZ><sZ>6 aut.</sZ></inist:fA14><country>République populaire de Chine</country><placeName><settlement type="city">Pékin</settlement></placeName></affiliation></author><author><name sortKey="Cong, D Y" uniqKey="Cong D">D. Y. Cong</name><affiliation wicri:level="1"><inist:fA14 i1="02"><s1>Institute for Metallic Materials, IFW Dresden, P.O. Box 270116</s1><s2>01171 Dresden</s2><s3>DEU</s3><sZ>2 aut.</sZ></inist:fA14><country>Allemagne</country><wicri:noRegion>01171 Dresden</wicri:noRegion><wicri:noRegion>270116</wicri:noRegion><wicri:noRegion>01171 Dresden</wicri:noRegion></affiliation></author><author><name sortKey="Nie, Z H" uniqKey="Nie Z">Z. H. Nie</name><affiliation wicri:level="1"><inist:fA14 i1="01"><s1>School of Materials Science and Engineering, Beijing Institute of Technology</s1><s2>Beijing 100081</s2><s3>CHN</s3><sZ>1 aut.</sZ><sZ>3 aut.</sZ><sZ>6 aut.</sZ></inist:fA14><country>République populaire de Chine</country><placeName><settlement type="city">Pékin</settlement></placeName></affiliation></author><author><name sortKey="Gao, J" uniqKey="Gao J">J. Gao</name><affiliation wicri:level="1"><inist:fA14 i1="03"><s1>Key Laboratory of Electromagnetic Processing of Materials (Ministry of Education), Northeastern University</s1><s2>Shenyang 110004</s2><s3>CHN</s3><sZ>4 aut.</sZ></inist:fA14><country>République populaire de Chine</country><wicri:noRegion>Shenyang 110004</wicri:noRegion></affiliation></author><author><name sortKey="Liu, W" uniqKey="Liu W">W. Liu</name><affiliation wicri:level="1"><inist:fA14 i1="04"><s1>X-Ray Science Division, Argonne National Laboratory</s1><s2>Argonne, IL 60439</s2><s3>USA</s3><sZ>5 aut.</sZ></inist:fA14><country>États-Unis</country><wicri:noRegion>Argonne, IL 60439</wicri:noRegion></affiliation></author><author><name sortKey="Wang, Y D" uniqKey="Wang Y">Y. D. Wang</name><affiliation wicri:level="1"><inist:fA14 i1="01"><s1>School of Materials Science and Engineering, Beijing Institute of Technology</s1><s2>Beijing 100081</s2><s3>CHN</s3><sZ>1 aut.</sZ><sZ>3 aut.</sZ><sZ>6 aut.</sZ></inist:fA14><country>République populaire de Chine</country><placeName><settlement type="city">Pékin</settlement></placeName></affiliation></author></titleStmt><publicationStmt><idno type="inist">12-0105038</idno><date when="2012">2012</date><idno type="stanalyst">PASCAL 12-0105038 INIST</idno><idno type="RBID">Pascal:12-0105038</idno><idno type="wicri:Area/Main/Corpus">002137</idno><idno type="wicri:Area/Main/Repository">001356</idno><idno type="wicri:Area/Chine/Extraction">000365</idno></publicationStmt><seriesStmt><idno type="ISSN">0925-8388</idno><title level="j" type="abbreviated">J. alloys compd.</title><title level="j" type="main">Journal of alloys and compounds</title></seriesStmt></fileDesc><profileDesc><textClass><keywords scheme="KwdEn" xml:lang="en"><term>Annealing</term><term>Cobalt alloys</term><term>Dendrites</term><term>Differential scanning calorimetry</term><term>Indium alloys</term><term>Magnetic alloy</term><term>Manganese alloys</term><term>Martensitic transformations</term><term>Microstructure</term><term>Nickel alloys</term><term>Precipitation</term><term>Quaternary alloys</term><term>Scanning electron microscopy</term><term>Shape memory alloy</term><term>Supercooling</term><term>Transition element alloys</term></keywords><keywords scheme="Pascal" xml:lang="fr"><term>Microstructure</term><term>Transformation martensitique</term><term>Surfusion</term><term>Microscopie électronique balayage</term><term>Précipitation</term><term>Dendrite</term><term>Calorimétrie différentielle balayage</term><term>Recuit</term><term>Alliage quaternaire</term><term>Alliage magnétique</term><term>Nickel alliage</term><term>Alliage mémoire forme</term><term>Cobalt alliage</term><term>Manganèse alliage</term><term>Indium alliage</term><term>Métal transition alliage</term></keywords></textClass></profileDesc></teiHeader><front><div type="abstract" xml:lang="en">The intrinsic mechanism of the martensitic transformation (MT) suppression observed in Ni-Co-Mn-In alloys fabricated under non-equilibrium conditions still remains mysterious. Here, we used the undercooling technique to obtain a solidified microstructure in non-equilibrium state, subsequently leading to MT suppression even further cooling to 10 K. It was found that primary dendrite-like In-depleted precipitates occurred during solidification under a large undercooling. After a prolonged annealing, the MT interestingly appeared again due to the dissolution of the precipitates and the recovery of equilibrium chemical composition in the matrix.</div></front></TEI><inist><standard h6="B"><pA><fA01 i1="01" i2="1"><s0>0925-8388</s0></fA01><fA03 i2="1"><s0>J. alloys compd.</s0></fA03><fA05><s2>511</s2></fA05><fA06><s2>1</s2></fA06><fA08 i1="01" i2="1" l="ENG"><s1>The suppression and recovery of martensitic transformation in a Ni-Co-Mn-In magnetic shape memory alloy</s1></fA08><fA11 i1="01" i2="1"><s1>WANG (Z. L.)</s1></fA11><fA11 i1="02" i2="1"><s1>CONG (D. Y.)</s1></fA11><fA11 i1="03" i2="1"><s1>NIE (Z. H.)</s1></fA11><fA11 i1="04" i2="1"><s1>GAO (J.)</s1></fA11><fA11 i1="05" i2="1"><s1>LIU (W.)</s1></fA11><fA11 i1="06" i2="1"><s1>WANG (Y. D.)</s1></fA11><fA14 i1="01"><s1>School of Materials Science and Engineering, Beijing Institute of Technology</s1><s2>Beijing 100081</s2><s3>CHN</s3><sZ>1 aut.</sZ><sZ>3 aut.</sZ><sZ>6 aut.</sZ></fA14><fA14 i1="02"><s1>Institute for Metallic Materials, IFW Dresden, P.O. Box 270116</s1><s2>01171 Dresden</s2><s3>DEU</s3><sZ>2 aut.</sZ></fA14><fA14 i1="03"><s1>Key Laboratory of Electromagnetic Processing of Materials (Ministry of Education), Northeastern University</s1><s2>Shenyang 110004</s2><s3>CHN</s3><sZ>4 aut.</sZ></fA14><fA14 i1="04"><s1>X-Ray Science Division, Argonne National Laboratory</s1><s2>Argonne, IL 60439</s2><s3>USA</s3><sZ>5 aut.</sZ></fA14><fA20><s1>41-44</s1></fA20><fA21><s1>2012</s1></fA21><fA23 i1="01"><s0>ENG</s0></fA23><fA43 i1="01"><s1>INIST</s1><s2>1151</s2><s5>354000506771120090</s5></fA43><fA44><s0>0000</s0><s1>© 2012 INIST-CNRS. All rights reserved.</s1></fA44><fA45><s0>12 ref.</s0></fA45><fA47 i1="01" i2="1"><s0>12-0105038</s0></fA47><fA60><s1>P</s1></fA60><fA61><s0>A</s0></fA61><fA64 i1="01" i2="1"><s0>Journal of alloys and compounds</s0></fA64><fA66 i1="01"><s0>GBR</s0></fA66><fC01 i1="01" l="ENG"><s0>The intrinsic mechanism of the martensitic transformation (MT) suppression observed in Ni-Co-Mn-In alloys fabricated under non-equilibrium conditions still remains mysterious. Here, we used the undercooling technique to obtain a solidified microstructure in non-equilibrium state, subsequently leading to MT suppression even further cooling to 10 K. It was found that primary dendrite-like In-depleted precipitates occurred during solidification under a large undercooling. After a prolonged annealing, the MT interestingly appeared again due to the dissolution of the precipitates and the recovery of equilibrium chemical composition in the matrix.</s0></fC01><fC02 i1="01" i2="3"><s0>001B80A30K</s0></fC02><fC02 i1="02" i2="3"><s0>001B80A30M</s0></fC02><fC03 i1="01" i2="3" l="FRE"><s0>Microstructure</s0><s5>02</s5></fC03><fC03 i1="01" i2="3" l="ENG"><s0>Microstructure</s0><s5>02</s5></fC03><fC03 i1="02" i2="3" l="FRE"><s0>Transformation martensitique</s0><s5>03</s5></fC03><fC03 i1="02" i2="3" l="ENG"><s0>Martensitic transformations</s0><s5>03</s5></fC03><fC03 i1="03" i2="3" l="FRE"><s0>Surfusion</s0><s5>04</s5></fC03><fC03 i1="03" i2="3" l="ENG"><s0>Supercooling</s0><s5>04</s5></fC03><fC03 i1="04" i2="3" l="FRE"><s0>Microscopie électronique balayage</s0><s5>05</s5></fC03><fC03 i1="04" i2="3" l="ENG"><s0>Scanning electron microscopy</s0><s5>05</s5></fC03><fC03 i1="05" i2="3" l="FRE"><s0>Précipitation</s0><s5>06</s5></fC03><fC03 i1="05" i2="3" l="ENG"><s0>Precipitation</s0><s5>06</s5></fC03><fC03 i1="06" i2="3" l="FRE"><s0>Dendrite</s0><s5>07</s5></fC03><fC03 i1="06" i2="3" l="ENG"><s0>Dendrites</s0><s5>07</s5></fC03><fC03 i1="07" i2="3" l="FRE"><s0>Calorimétrie différentielle balayage</s0><s5>09</s5></fC03><fC03 i1="07" i2="3" l="ENG"><s0>Differential scanning calorimetry</s0><s5>09</s5></fC03><fC03 i1="08" i2="3" l="FRE"><s0>Recuit</s0><s5>10</s5></fC03><fC03 i1="08" i2="3" l="ENG"><s0>Annealing</s0><s5>10</s5></fC03><fC03 i1="09" i2="3" l="FRE"><s0>Alliage quaternaire</s0><s5>12</s5></fC03><fC03 i1="09" i2="3" l="ENG"><s0>Quaternary alloys</s0><s5>12</s5></fC03><fC03 i1="10" i2="X" l="FRE"><s0>Alliage magnétique</s0><s5>16</s5></fC03><fC03 i1="10" i2="X" l="ENG"><s0>Magnetic alloy</s0><s5>16</s5></fC03><fC03 i1="10" i2="X" l="SPA"><s0>Aleación magnética</s0><s5>16</s5></fC03><fC03 i1="11" i2="3" l="FRE"><s0>Nickel alliage</s0><s5>17</s5></fC03><fC03 i1="11" i2="3" l="ENG"><s0>Nickel alloys</s0><s5>17</s5></fC03><fC03 i1="12" i2="X" l="FRE"><s0>Alliage mémoire forme</s0><s5>18</s5></fC03><fC03 i1="12" i2="X" l="ENG"><s0>Shape memory alloy</s0><s5>18</s5></fC03><fC03 i1="12" i2="X" l="SPA"><s0>Aleación memoria forma</s0><s5>18</s5></fC03><fC03 i1="13" i2="3" l="FRE"><s0>Cobalt alliage</s0><s5>19</s5></fC03><fC03 i1="13" i2="3" l="ENG"><s0>Cobalt alloys</s0><s5>19</s5></fC03><fC03 i1="14" i2="3" l="FRE"><s0>Manganèse alliage</s0><s5>20</s5></fC03><fC03 i1="14" i2="3" l="ENG"><s0>Manganese alloys</s0><s5>20</s5></fC03><fC03 i1="15" i2="3" l="FRE"><s0>Indium alliage</s0><s5>21</s5></fC03><fC03 i1="15" i2="3" l="ENG"><s0>Indium alloys</s0><s5>21</s5></fC03><fC03 i1="16" i2="3" l="FRE"><s0>Métal transition alliage</s0><s5>48</s5></fC03><fC03 i1="16" i2="3" l="ENG"><s0>Transition element alloys</s0><s5>48</s5></fC03><fN21><s1>079</s1></fN21></pA></standard></inist></record>Pour manipuler ce document sous Unix (Dilib)
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