Qiu Feng, Zhengwei Xiong, Zhangyang Zhou, Jun Yang, Gang Yao, Sen Chen, Zeming Tang, Zhipeng Gao
{"title":"冲击压缩下铌酸钾的动态相变模型","authors":"Qiu Feng, Zhengwei Xiong, Zhangyang Zhou, Jun Yang, Gang Yao, Sen Chen, Zeming Tang, Zhipeng Gao","doi":"10.1103/physrevb.110.174102","DOIUrl":null,"url":null,"abstract":"The phase transitions of ferroelectric ceramics under dynamic compressions are of importance for materials and applications design. However, there are very few effective methods for describing the shock-induced phase transition process in ferroelectric ceramics, due to the tiny structural volume change during compression. Here the phase transition behaviors of <mjx-container ctxtmenu_counter=\"10\" ctxtmenu_oldtabindex=\"1\" jax=\"CHTML\" overflow=\"linebreak\" role=\"tree\" sre-explorer- style=\"font-size: 100.7%;\" tabindex=\"0\"><mjx-math data-semantic-structure=\"(5 0 4 (3 1 2))\"><mjx-mrow data-semantic-annotation=\"clearspeak:unit\" data-semantic-children=\"0,3\" data-semantic-content=\"4\" data-semantic- data-semantic-owns=\"0 4 3\" data-semantic-role=\"implicit\" data-semantic-speech=\"upper K upper N b normal upper O 3\" data-semantic-type=\"infixop\"><mjx-mi data-semantic-font=\"normal\" data-semantic- data-semantic-parent=\"5\" data-semantic-role=\"unknown\" data-semantic-type=\"identifier\"><mjx-c noic=\"true\" style=\"padding-top: 0.706em;\">K</mjx-c><mjx-c noic=\"true\" style=\"padding-top: 0.706em;\">N</mjx-c><mjx-c style=\"padding-top: 0.706em;\">b</mjx-c></mjx-mi><mjx-mo data-semantic-added=\"true\" data-semantic- data-semantic-operator=\"infixop,\" data-semantic-parent=\"5\" data-semantic-role=\"multiplication\" data-semantic-type=\"operator\"><mjx-c></mjx-c></mjx-mo><mjx-msub data-semantic-children=\"1,2\" data-semantic- data-semantic-owns=\"1 2\" data-semantic-parent=\"5\" data-semantic-role=\"latinletter\" data-semantic-type=\"subscript\" space=\"2\"><mjx-mi data-semantic-annotation=\"clearspeak:simple\" data-semantic-font=\"normal\" data-semantic- data-semantic-parent=\"3\" data-semantic-role=\"latinletter\" data-semantic-type=\"identifier\"><mjx-c>O</mjx-c></mjx-mi><mjx-script style=\"vertical-align: -0.15em;\"><mjx-mn data-semantic-annotation=\"clearspeak:simple\" data-semantic-font=\"normal\" data-semantic- data-semantic-parent=\"3\" data-semantic-role=\"integer\" data-semantic-type=\"number\" size=\"s\"><mjx-c>3</mjx-c></mjx-mn></mjx-script></mjx-msub></mjx-mrow></mjx-math></mjx-container> ceramics under compression are studied by measuring electrical responses. A model describing the phase variation in ferroelectric ceramics under uniaxial compressions with respect to pressures has been established, which may provide a reference for studying dynamic phase transitions in ferroelectrics under shock waves. Unlike hydrostatic high-pressure processes, the shock-induced phase transition initiates at relatively low pressures and increases progressively as the pressure rises. Random orientations of the grains in ceramics lead to different pressure conditions of each grain, which is responsible for the gradual phase transition processes. The proportion of phase transitions in three-dimensional space can be visualized using <i>ab initio</i> density functional theory. These findings have significant implications for material design and optimization.","PeriodicalId":20082,"journal":{"name":"Physical Review B","volume":"7 1","pages":""},"PeriodicalIF":3.7000,"publicationDate":"2024-11-05","publicationTypes":"Journal Article","fieldsOfStudy":null,"isOpenAccess":false,"openAccessPdf":"","citationCount":"0","resultStr":"{\"title\":\"Dynamic phase transition modeling of potassium niobate under shock compression\",\"authors\":\"Qiu Feng, Zhengwei Xiong, Zhangyang Zhou, Jun Yang, Gang Yao, Sen Chen, Zeming Tang, Zhipeng Gao\",\"doi\":\"10.1103/physrevb.110.174102\",\"DOIUrl\":null,\"url\":null,\"abstract\":\"The phase transitions of ferroelectric ceramics under dynamic compressions are of importance for materials and applications design. However, there are very few effective methods for describing the shock-induced phase transition process in ferroelectric ceramics, due to the tiny structural volume change during compression. Here the phase transition behaviors of <mjx-container ctxtmenu_counter=\\\"10\\\" ctxtmenu_oldtabindex=\\\"1\\\" jax=\\\"CHTML\\\" overflow=\\\"linebreak\\\" role=\\\"tree\\\" sre-explorer- style=\\\"font-size: 100.7%;\\\" tabindex=\\\"0\\\"><mjx-math data-semantic-structure=\\\"(5 0 4 (3 1 2))\\\"><mjx-mrow data-semantic-annotation=\\\"clearspeak:unit\\\" data-semantic-children=\\\"0,3\\\" data-semantic-content=\\\"4\\\" data-semantic- data-semantic-owns=\\\"0 4 3\\\" data-semantic-role=\\\"implicit\\\" data-semantic-speech=\\\"upper K upper N b normal upper O 3\\\" data-semantic-type=\\\"infixop\\\"><mjx-mi data-semantic-font=\\\"normal\\\" data-semantic- data-semantic-parent=\\\"5\\\" data-semantic-role=\\\"unknown\\\" data-semantic-type=\\\"identifier\\\"><mjx-c noic=\\\"true\\\" style=\\\"padding-top: 0.706em;\\\">K</mjx-c><mjx-c noic=\\\"true\\\" style=\\\"padding-top: 0.706em;\\\">N</mjx-c><mjx-c style=\\\"padding-top: 0.706em;\\\">b</mjx-c></mjx-mi><mjx-mo data-semantic-added=\\\"true\\\" data-semantic- data-semantic-operator=\\\"infixop,\\\" data-semantic-parent=\\\"5\\\" data-semantic-role=\\\"multiplication\\\" data-semantic-type=\\\"operator\\\"><mjx-c></mjx-c></mjx-mo><mjx-msub data-semantic-children=\\\"1,2\\\" data-semantic- data-semantic-owns=\\\"1 2\\\" data-semantic-parent=\\\"5\\\" data-semantic-role=\\\"latinletter\\\" data-semantic-type=\\\"subscript\\\" space=\\\"2\\\"><mjx-mi data-semantic-annotation=\\\"clearspeak:simple\\\" data-semantic-font=\\\"normal\\\" data-semantic- data-semantic-parent=\\\"3\\\" data-semantic-role=\\\"latinletter\\\" data-semantic-type=\\\"identifier\\\"><mjx-c>O</mjx-c></mjx-mi><mjx-script style=\\\"vertical-align: -0.15em;\\\"><mjx-mn data-semantic-annotation=\\\"clearspeak:simple\\\" data-semantic-font=\\\"normal\\\" data-semantic- data-semantic-parent=\\\"3\\\" data-semantic-role=\\\"integer\\\" data-semantic-type=\\\"number\\\" size=\\\"s\\\"><mjx-c>3</mjx-c></mjx-mn></mjx-script></mjx-msub></mjx-mrow></mjx-math></mjx-container> ceramics under compression are studied by measuring electrical responses. A model describing the phase variation in ferroelectric ceramics under uniaxial compressions with respect to pressures has been established, which may provide a reference for studying dynamic phase transitions in ferroelectrics under shock waves. Unlike hydrostatic high-pressure processes, the shock-induced phase transition initiates at relatively low pressures and increases progressively as the pressure rises. Random orientations of the grains in ceramics lead to different pressure conditions of each grain, which is responsible for the gradual phase transition processes. The proportion of phase transitions in three-dimensional space can be visualized using <i>ab initio</i> density functional theory. 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Dynamic phase transition modeling of potassium niobate under shock compression
The phase transitions of ferroelectric ceramics under dynamic compressions are of importance for materials and applications design. However, there are very few effective methods for describing the shock-induced phase transition process in ferroelectric ceramics, due to the tiny structural volume change during compression. Here the phase transition behaviors of KNbO3 ceramics under compression are studied by measuring electrical responses. A model describing the phase variation in ferroelectric ceramics under uniaxial compressions with respect to pressures has been established, which may provide a reference for studying dynamic phase transitions in ferroelectrics under shock waves. Unlike hydrostatic high-pressure processes, the shock-induced phase transition initiates at relatively low pressures and increases progressively as the pressure rises. Random orientations of the grains in ceramics lead to different pressure conditions of each grain, which is responsible for the gradual phase transition processes. The proportion of phase transitions in three-dimensional space can be visualized using ab initio density functional theory. These findings have significant implications for material design and optimization.
期刊介绍:
Physical Review B (PRB) is the world’s largest dedicated physics journal, publishing approximately 100 new, high-quality papers each week. The most highly cited journal in condensed matter physics, PRB provides outstanding depth and breadth of coverage, combined with unrivaled context and background for ongoing research by scientists worldwide.
PRB covers the full range of condensed matter, materials physics, and related subfields, including:
-Structure and phase transitions
-Ferroelectrics and multiferroics
-Disordered systems and alloys
-Magnetism
-Superconductivity
-Electronic structure, photonics, and metamaterials
-Semiconductors and mesoscopic systems
-Surfaces, nanoscience, and two-dimensional materials
-Topological states of matter