Magnesium alloys have emerged as promising light weight materials due to their low density,high specific strength,excellent machinability,and superior damping capacity,making them ideal for aerospace,automotive,and el...Magnesium alloys have emerged as promising light weight materials due to their low density,high specific strength,excellent machinability,and superior damping capacity,making them ideal for aerospace,automotive,and electronics applications.However,broader use of magnesium alloys is limited by poor thermo-mechanical performance,corrosion susceptibility,and low formability at room temperature.The addition of rare-earth elements such as gadolinium,yttrium,and neodymium has meaningfully improved these limitations,enhancing the overall performance of magnesium alloys.This review highlights recent advancements in rare-earth magnesium alloys,focusing on their improved thermo-mechanical properties,microstructural evolution,crystallization behavior,and texture development.Herein,strengthening mechanisms associated with rare-earth additions are discussed in detail.Furthermore,the article explores growing relevance of these alloys in advanced applications,including biomedical implants,Io T devices,aerospace structures,defense systems,and general engineering.With their enhanced mechanical and functional properties,rare-earth magnesium alloys represent a new generation of high-performance,functional materials poised to drive innovation across multiple technology sectors.展开更多
Four BT-based ceramic samples were prepared using a grain grading approach.The bigger-grained(~100 nm)and smaller-grained(~70 nm)BaTiO_(3)(BT)powders were mixed.The smaller-grained BT powder controlled the average gra...Four BT-based ceramic samples were prepared using a grain grading approach.The bigger-grained(~100 nm)and smaller-grained(~70 nm)BaTiO_(3)(BT)powders were mixed.The smaller-grained BT powder controlled the average grain size and guaranteed the reliability,while the bigger-grained powder enhanced the dielectric constant.Various percentages of bigger-grained BT powder were introduced to balance the average grain size and the dielectric constant.As the proportion of bigger grains increased,the dielectric constant(εr)improved significantly.The room-temperatureεr of 25%bigger-grain mixed BT(2623)was~50%higher than that of the sample with a similar average grain size without grain grading.The ceramic mixed with 15%bigger-grained BT showed comprehensive dielectric performance,which met the EIA X5R standard and provided a considerableεr of 1841 along with a low dielectric loss of 0.78%.Notably,the average grain size was 90 nm,which favors the applications in ultra-thin multilayer ceramic capacitors.展开更多
The growing demand for high-power-density electric and electronic systems has encouraged the development of energy-storage capacitors with attributes such as high energy density,high capacitance density,high voltage a...The growing demand for high-power-density electric and electronic systems has encouraged the development of energy-storage capacitors with attributes such as high energy density,high capacitance density,high voltage and frequency,low weight,high-temperature operability,and environmental friendliness.Compared with their electrolytic and film counterparts,energy-storage multilayer ceramic capacitors(MLCCs)stand out for their extremely low equivalent series resistance and equivalent series inductance,high current handling capability,and high-temperature stability.These characteristics are important for applications including fast-switching third-generation wide-bandgap semiconductors in electric vehicles,5G base stations,clean energy generation,and smart grids.There have been numerous reports on state-of-the-art MLCC energy-storage solutions.However,lead-free capacitors generally have a low-energy density,and high-energy density capacitors frequently contain lead,which is a key issue that hinders their broad application.In this review,we present perspectives and challenges for lead-free energy-storage MLCCs.Initially,the energy-storage mechanism and device characterization are introduced;then,dielectric ceramics for energy-storage applications with aspects of composition and structural optimization are summarized.Progress on state-of-the-art energy-storage MLCCs is discussed after elaboration of the fabrication process and structural design of the electrode.Emerging applications of energy-storage MLCCs are then discussed in terms of advanced pulsed power sources and high-density power converters from a theoretical and technological point of view.Finally,the challenges and future prospects for industrialization of lab-scale lead-free energy-storage MLCCs are discussed.展开更多
基金the support of the SPARC project(P3808)UKIERI-4 Strand 1 Institutional Research&Mobility Partnerships Grant(45580615 UKIERISPARC/01/18)under the Indo-UK schemeSKT extends heartfelt gratitude to Nitte University for providing the research grant(grant no.NUFR-23-070)。
文摘Magnesium alloys have emerged as promising light weight materials due to their low density,high specific strength,excellent machinability,and superior damping capacity,making them ideal for aerospace,automotive,and electronics applications.However,broader use of magnesium alloys is limited by poor thermo-mechanical performance,corrosion susceptibility,and low formability at room temperature.The addition of rare-earth elements such as gadolinium,yttrium,and neodymium has meaningfully improved these limitations,enhancing the overall performance of magnesium alloys.This review highlights recent advancements in rare-earth magnesium alloys,focusing on their improved thermo-mechanical properties,microstructural evolution,crystallization behavior,and texture development.Herein,strengthening mechanisms associated with rare-earth additions are discussed in detail.Furthermore,the article explores growing relevance of these alloys in advanced applications,including biomedical implants,Io T devices,aerospace structures,defense systems,and general engineering.With their enhanced mechanical and functional properties,rare-earth magnesium alloys represent a new generation of high-performance,functional materials poised to drive innovation across multiple technology sectors.
基金supported by Ministry of Science and Technology of China through The Key Area Research Plan of Guangdong(Grant No.2019B010937001)High-end MLCC Key Project supported by Guangdong Fenghua Advanced Technology Holding Co.,Ltd.(No.20212001429)+1 种基金the National Key Research and Development Program of China(No.2017YFB0406302)the National Natural Science Foundation of China(No.52032005).
文摘Four BT-based ceramic samples were prepared using a grain grading approach.The bigger-grained(~100 nm)and smaller-grained(~70 nm)BaTiO_(3)(BT)powders were mixed.The smaller-grained BT powder controlled the average grain size and guaranteed the reliability,while the bigger-grained powder enhanced the dielectric constant.Various percentages of bigger-grained BT powder were introduced to balance the average grain size and the dielectric constant.As the proportion of bigger grains increased,the dielectric constant(εr)improved significantly.The room-temperatureεr of 25%bigger-grain mixed BT(2623)was~50%higher than that of the sample with a similar average grain size without grain grading.The ceramic mixed with 15%bigger-grained BT showed comprehensive dielectric performance,which met the EIA X5R standard and provided a considerableεr of 1841 along with a low dielectric loss of 0.78%.Notably,the average grain size was 90 nm,which favors the applications in ultra-thin multilayer ceramic capacitors.
基金supported by National Key R&D Program of China(No.2017YFB0406302)Key-Area Research and Development Program of Guangdong Province(No.2019B090912003)+2 种基金the National Natural Science Foundation of China(No.52002253)Sichuan Science and Technology Program(No.2021YFH0181)Shuimu Tsinghua Scholar Program,and State Key Laboratory of New Ceramic and Fine Processing Tsinghua University(No.KFZD202002).
文摘The growing demand for high-power-density electric and electronic systems has encouraged the development of energy-storage capacitors with attributes such as high energy density,high capacitance density,high voltage and frequency,low weight,high-temperature operability,and environmental friendliness.Compared with their electrolytic and film counterparts,energy-storage multilayer ceramic capacitors(MLCCs)stand out for their extremely low equivalent series resistance and equivalent series inductance,high current handling capability,and high-temperature stability.These characteristics are important for applications including fast-switching third-generation wide-bandgap semiconductors in electric vehicles,5G base stations,clean energy generation,and smart grids.There have been numerous reports on state-of-the-art MLCC energy-storage solutions.However,lead-free capacitors generally have a low-energy density,and high-energy density capacitors frequently contain lead,which is a key issue that hinders their broad application.In this review,we present perspectives and challenges for lead-free energy-storage MLCCs.Initially,the energy-storage mechanism and device characterization are introduced;then,dielectric ceramics for energy-storage applications with aspects of composition and structural optimization are summarized.Progress on state-of-the-art energy-storage MLCCs is discussed after elaboration of the fabrication process and structural design of the electrode.Emerging applications of energy-storage MLCCs are then discussed in terms of advanced pulsed power sources and high-density power converters from a theoretical and technological point of view.Finally,the challenges and future prospects for industrialization of lab-scale lead-free energy-storage MLCCs are discussed.
