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中国科学院上海硅酸盐研究所研究生导师简介-李永祥

上海硅酸盐研究所 /2013-05-12

李永祥 博士,研究员,博士生导师,中科院“百人计划”,上海市学科带头人。1984- 1991年在西安交通大学学习,获得电子材料与器件专业博士学位。1991-1996年在东南大学电子工程系任教; 1996-1998年期间在德国拜罗伊特大学(Universität of Bayreuth)物理系从事研究;1998-2000年期间在澳大利亚皇家墨尔本理工大学(RMIT University)通讯与电子工程系从事研究。1998年入选中科院“百人计划”(引进“国外杰出人才”计划)特聘为中国科学院上海硅酸盐研究所研究员。

    亚洲铁电理事会理事;IEEE高级会员;美国陶瓷学会会员;国际电介质研究中心理事;中国物理学会电介质专业学会副主任委员;中国电子学会高级会员;中国电子学会元件专业委员会第六~第十届委员会委员;上海硅酸盐学会特种陶瓷专委会主任委员;上海电子器件行业协会理事。

    重要学术刊物如《科学通报》、《无机材料学报》、《传感器技术学报》、《Sensors Letters》,《Journal of Sensors》,《Journal of Advanced Dielectrics》等期刊编委会成员(Member of Editorial Board),《Chinese Physics Letters》、《物理化学学报》等特约审稿等。

科研项目

    铌钛酸锂织构化陶瓷微结构及其微波介电可调性研究,国家自然科学基金面上项目,2012-2015
    新一代高性能压电材料及其应用基础研究,国际合作团队,2011-2014
    特种陶瓷材料研制,委托研究项目,2011-2012
    层状类钙钛矿铁电材料的结构与性能调控,国家自然科学基金重点项目,2010-2013
    高性能无铅压电陶瓷的微结构调控与性能,上海市优秀学科带头人,2010-2012
    高热导LTCC材料研究,所创新项目,2010-2012
    无源器件用系列化LTCC 材料及其关键技术的开发,广东省产学研结合项目,2010-2013
    用于大功率LED封装的高导热率LTCC陶瓷封装基板及封装技术研究,上海市科委半导体照明项目,2010-2012
    高性能电子陶瓷生带的制备及其产业化,省院作项目,2010-2012
    新型智能节能的示范应用系统构筑,973项目,2009-2013
    高性能压电陶瓷及其智能结构,973项目,2009-2013
    LTCC与无源集成器件工艺技术平台建设,创新重点项目,2009-2011
    量子点敏化的有序纳米TiO2-共轭聚合物异质结太阳能电池,上海-应用材料研究与发展基金,2009-2011
    高性能无铅压电材料准同型相界附近的相结构与性能研究,上海基础重点,2008- 2010
    纳米有序彩色电致变色薄膜的设计、合成与性能研究,国家自然科学基金项目,2008- 2010
    基于纳米结构薄膜的气体传感器研制,中-澳合作项目,2007- 2009
    铋层状共生电体的微结构设计及其电学特征性研究,国家自然科学基金项目,2006- 2008
    高度共轭聚合物纳米管的超快速电致变色特性的研究,上海市基础重点项目,2006- 2008
    高性能环境友好型压电换能器的研究,863项目,2006- 2008
    纳米复合半导体电极及紫外-可见光敏电致变色器件,三星公司合作研发项目,2004- 2009
    新型金属氧化物发光薄膜的制备及生长机制研究,上海市重点基金项目,2003- 2006
    纳米复合半导体电极及紫外-可见光敏光电致变色器件,上海市纳米专项,2003- 2005
    外场作用下信息功能陶瓷的结构变异及其对功能的影响机制,973项目,2002- 2008

编著-专著-章节

[1] 李永祥,殷庆瑞,《中国新材料产业发展报告2005》第7章:先进功能陶瓷材料,国家发改委高新技术产业司和中国材料研究学会,化学工业出版社, 2006年1月。

[2] Guest Editors: Michele Penza, Giorgio Sberveglieri, Wojtek Wlodarski, and Yongxiang Li. Special Issue NCST - Nanomaterial for Chemical Sensing Technologies Journal of Sensors - Open link: http://www.hindawi.com/journals/js/2009/si.1.htmlNanomaterials for Chemical Sensing Technologies.

[3]Guest editors / Symposium chairmen: Gavin Conibeer, Yongxiang Li, Jef Poortmans, Michio Condo, Abdelilah Slaoui, Meng Tao, Marko Topič, Special Issue of the Proceedings of EMRS 2011: European Materials Research Society Conference Symposium: Advanced Inorganic Materials and Concepts for Photovoltaics.

[4] 《无机材料学科前沿与展望》第11章。

[5] 上海市硅酸盐学会, 《上海地区精细陶瓷产业现状与发展报告》功能陶瓷部分(2011)。

[6] 《陶瓷百年史》磁性材料部分。

[7] 《大辞海》无机非金属材料卷。
 2012年

[173] Mingsheng Ma, Zhifu Liu, Yongxiang Li, Yuping Zeng, Dongxu Yao, Thermal conductivity of low-temperature sintered calcium aluminosilicate glass-silicon nitride whisker composites, Ceramics International, 2012, In press.

[172] Mingsheng Ma, Zhifu Liu, Yongxiang Li, Yuping Zeng, Dongxu Yao, Enhanced thermal conductivity of low-temperature sintered borosilicate glass-AlN composites with Si3N4 whiskers, Journal of the European Ceramic Society, 2012, In press.

[171] 王依琳,杨群保,吴文骏,李永祥,赖青贵,王华岑,龙继东,陶瓷介质在固态脉冲形成线中的应用,强激光与粒子束,8(2012)

[170] Changwei Shao, Yiqing Lu, Dong Wang, Yongxiang Li, Effect of Nd substitution on the microstructure and electrical properties of Bi7Ti4NbO21 piezoceramics, Journal of the European Ceramic Society 32, 3781 (2012).

[169] Teng Guo, Wenjun Wu, Yilin Wang, Yongxiang Li, Comparison for the crystal structure, synthesis and microwave dielectric properties of alkaline earth orthophosphates, Materials Chemistry and Physics 134, 503 (2012).

[168] Yun Liu, Lasse Noren, Andrew J. Studer, Ray L. Withers, Yiping Guo, Yongxiang Li, Hui Yang, Jian Wang, Response of intergrown microstructure to an electric field and its consequences in the lead-free piezoelectric bismuth sodium titanate, Journal of Solid State Chemistry 187, 309 (2012).

[167] Zhiyuan Lu, Yilin Wang, Wenjun Wu, Yongxiang Li, Textured Li0.95Nb0.45Ti0.7O3 Microwave Ceramics with Continuously Tunable Dielectric Properties, Ferroelectrics 429, 123 (2012).

[166] Youliang Wang, Yiqing Lu, Mengjia Wu, Dong Wang, Yongxiang Li, Low-temperature sintering and electrical properties of (K, Na)NbO3 based lead-free ceramics with high Curie temperature, Ceramics International 38, S295 (2012).

[165] Youliang Wang, Yiqing Lu, Mengjia Wu, Dong Wang, Yongxiang Li, Phase Structure and Enhanced Piezoelectric Properties of Lead-Free Ceramics (1-x)(K0.48Na0.52)NbO3-(x/5.15) K2.9Li1.95Nb5.15O15.3 with High Curie Temperature, International Journal of Applied Ceramic Technology 9, 221 (2012).

[164]Zhifu Liu, Yilin Wang, Yongxiang Li, Combinatorial study of ceramic tape-casting slurries, ACS Combinatorial Science, 14 (2012) 205-210.

[163] Zhifu Liu, Yiling Wang, Yongxiang Li, Combinatorial study on tape casting slurries, ACS combinatorial science, in press, (2012).

[162] 李亚利, 惠春, 李永祥, 王有亮,丝网印刷技术制备高性能织构化K0.45Na0.55NbO3陶瓷,无机材料学报, 27, 214-218 (2012).

[161] Teng Guo, Wenjun Wu, Yilin Wang, Yongxiang Li, Relations on synthesis, crystal structure and microwave dielectric properties of SrZnP2O7 ceramics, Ceramics International, 38, s187-s190 (2012).

[160] Yali Li, Chun Hui, Mengjia Wu, Yongxiang Li, Youliang Wang, Textured (K0.5Na0.5)NbO3 ceramics prepared by screen-printing multilayer grain growth technique, Ceramics International, 38, s283-s286 (2012).

[159] 文豪,刘志甫,杨群保,李永祥,CeO2修饰的透明TiO2纳米管电极的电致变色器件,无机材料学报, 27, 74-79 (2012).
 2011

[158] Pan Wang, Yongxiang Li, Yiqing Lu, Enhanced Piezoelectric Properties of (Ba0.85Ca0.15)(Ti0.9Zr0.1)O3 Lead-free Ceramics by Optimizing Calcination and Sintering Temperature, Journal of the European Ceramic Society, 31, 2005–2012 (2011).

[157] Hao Wen,Zhifu Liu, Qunbao Yang, Yongxiang Li, Jerry Yu, Synthesis and Electrochemical Properties of CeO2 Nanoparticle Modified TiO2 Nanotube Arrays, Electrochim. Acta,56, 2914-2918 (2011).

[156] Hao Wen,Zhifu Liu, Jiao Wang, Qunbao Yang, Yongxiang Li, Jerry Yu, Facile Synthesis of Nb2O5 Nanorod Array Films and Their Electrochemical Properties, Appl. Surf. Sci,.257, 10084-10088 (2011).

[155] Zhiyuan Lu,Yali Li, Yilin Wang, Wenjun Wu, Yongxiang Li, Anisotropic Dielectric Properties of LiNb0.6Ti0.5O3 Microwave Ceramics by Screen-Printing Templated Grain Growth, Journal of American Cermaic Society,94, 4364-4370(2011).

[154] Zhiyuan Lu,Yilin Wang, Wenjun Wu, Yongxiang Li, Morphology and Structure of LiNb0.6Ti0.5O3 Particles by Molten Salt Synthesis, Journal of Alloys and Compounds,509, 9696-9701(2011).

[153] Z. G. Yi, Y. X. Li, Y. Liu, Ferroelectric and Piezoelectric Properties of Aurivillius Phase Intergrowth Ferroelectrics and the Underlying Materials Design, Phys. Status Solidi A-Appl. Mat.,208, 1035-1040(2011).

[152] Mengjia Wu, Youliang Wang, Dong Wang, Yongxiang Li, Enhanced electrical properties of textured NBBT ceramics derived from the screen printing technique, IEEE Trans. Ultrason. Ferroelectr. Freq. Control,58, 2036-2041 (2011).

[151] Zhengfa Li, Yongxiang Li, Jiwei Zhai, Grain growth and piezoelectric property of KNN-based lead-free ceramics, Current Applied Physics,11, S2-S13 (2011).

[150] Yali Li, Chun Hui, Yongxiang Li, Youliang Wang, Preparation of textured K2BiNb5O15 ceramics with rod-like templates by the screen-printing technique,Journal of Alloys and Compounds, 509, L203-L207(2011).

[149] Yiqing Lu, and Yongxiang Li, A Review on Lead-free Piezoelectric CeramicsStudies in China,Journal of Advanced Dielectrics,1, 269–288 (2011).

[148] X. Gao, H. Gu, Y. X. Li, Z. G. Yi, M. Ceh, K. Zagar, Structural evolution of the intergrowth bismuth-layered Bi7Ti4NbO21, Journal of Materials Science, 46, 5423-5431(2011).

[147] Jigong Hao, Jiwei Zhai, Yongxiang Li, Preparation of (K0.50Na0.50)NbO3 Lead-Free Piezoelectric Ceramics by Mechanical Activation Assisted Method, Jpn. J. Appl. Phys., 50, 110207(2011).

[146] J. Yu, J. Liu, M. Breedon, M. Shafiei, H. Wen, Y. X. Li, W. Wlodarski, G. Zhang, K. Kalantar-zadeh,The correlation between electric field emission phenomenon and Schottky contact reverse bias characteristics in nanostructured systems, Journal of Applied Physics 109, 114316(2011).

[145] Hong-zhang SONG, Hua-rong ZENG, Yong-xiang LI, Qing-rui YIN, Xing HU, Ferroic domain characterization of Ni55Mn20.6Ga24.4 ferromagnetic shape memory alloy, Trans. Nonferrous Met. Soc. China, 21, 2015-2019(2011).
 2010

[144] Mengjia Wu, Yongxiang Li, Topochemical synthesis of plate-like Na0.5Bi0.5TiO3 templates from Bi4Ti3O12, Materials Letters,64, 1157–1159(2010).

[143] Yu Zhao, Yongxiang Li, Yiqing Lu, and Yilin Wang, The Formation Mechanism of Intergrowth Bismuth Layer-Structured Ferroelectric Bi4Ti3O12-CaBi4Ti4O15, Ferroelectrics, 404, 45–49 (2010).

[142] Teng Guo, Yongxiang Li, Yilin Wang, Wenjun Wu, Effect of Sr/P Ratio on the Microwave Dielectric Properties of Sr2P2O7 Ceramics,Ferroelectrics, 407, 84–92(2010).

[141] Zhengfa Li, H. L. W. Chan, Yongxiang Li, K. W. Kwok, S. H. Choy, Anisotropic properties and crystal structure of ferroelectric Na0.5Bi4.5Ti4O15, Journal of Alloys and Compounds, 506, 70–72(2010).

[140] J. Yu, M. Shafiei, W. Wlodarski, Y. X. Li, K. Kalantar-Zadeh, Enhancement of electric field properties of Pt/nanoplatelet MoO3/SiC Schottky diode,Journal of Physics D-Applied Physics, 43,025103 (2010).

[139] M. B. Rahmani, S. H. Keshmiri, J. Yu, A. Z. Sadek, L. Al-Mashat, A. Moafi, K. Latham, Y. X. Li, W. Wlodarski, K. Kalantar-zadeh, Gas sensing properties of thermally evaporated lamellar MoO3, Sens. Actuator B-Chem., 145, 13–19(2010).
 2009

[138] X. F. Yu, Y. X. Li, K. Kalantar-Zadeh, Synthesis and electrochemical properties of template-based polyaniline nanowires and template-free nanofibril arrays: Two potential nanostructures for gas sensors,Sens. Actuator B, 136, 1–7 (2009).

[137] Yanping Long, Yilin Wang, Wenjun Wu, Dong Wang, Yongxiang Li, Sintering and Microwave Dielectric Properties of the LiNb0.63Ti0.4625O3 Ceramics with the B2O3–SiO2 Liquid-Phase Additives, Journal of American Cermaic Society, 92, 2630–2633 (2009).

[136] Y. P. Long, Y. X. Li, Y. L. Wang, W. J. Wu, Synthesis and characterization of Li–Nb–Ti–O dielectric material by the citrate sol–gel method,Journal of Alloys and Compounds, 475, 546–550(2009).

[135] H. Z. Song, Y. X. Li, K. Y. Zhao, H. R. Zeng, S. X. Hui, G. R. Li, Q. R. Yin, G. H. Wu, Influence of stress on the magnetic domain structure in Fe81Ga19 alloys,Journal of Applied Physics, 105, 013913 (2009).

[134] H. Z. Song, Y. X. Li, K. Y. Zhao, H. R. Zeng, G. R. Li, Q. R. Yin, Scanning acoustic microscopy of ferroic materials under stress, Journal of Material Research, 24, 2173–2178(2009).

[133] H. Z. Song, Y. X. Li, K. Y. Zhao, H. R. Zeng, S. X. Hui, G. R. Li, Q. R. Yin, Direct and simultaneous observation of ferroelectric and magnetic domains,Materials Letters, 63, 589–591 (2009).

[132] M. J. Wu, Y. X. Li, D. Wang, J. T. Zeng, Q. R. Yin, Grain oriented (Na0.5Bi0.5)0.94Ba0.06TiO3 piezoceramics prepared by the screen-printing multilayer grain growth technique, Journal of Electroceramics, 22, 131–135(2009).

[131] L. J. Ma, Y. X. Li, X. F. Yu, Q. B. Yang, C. H. Noh, Fabricating red–blue-switching dual polymer electrochromic devices using room temperature ionic liquid,Sol. Energy Mater. Sol. Cells, 93, 564–570(2009).

[130] Z. Wang, W. W. Wu, Q. B. Yang, Y. X. Li, C. H. Noh, In-situ fabrication of flexible vertically integrated electronic circuits by inkjet printing,Journal of Alloys and Compounds,486, 706–710(2009).

[129] Z. Wang, Y. X. Li, Improvement in Dielectric Tunability of Ba0.6Sr0.4TiO4–Mg2TiO4Composite Ceramics via Heterogeneous Nucleation Processing,Chin. Phys. Lett.,26,117701 (2009).

[128] R. Arsat, X. F. Yu, Y. X. Li, W. Wlodarski, K. Kalantar-zadeh, Hydrogen Gas Sensor Based on Highly Ordered Polyaniline Nanofibers,Sens. Actuator B, 137, 529–532(2009).

[127] K. Kalantar-Zadeh, A. Z. Sadek, J. G. Partridge, D. G. McCulloch, Y. X. Li, X. F. Yu, P. G. Spizzirri, W. Wlodarski, Nanoporous titanium oxide synthesized from anodized Filtered Cathodic Vacuum Arc Ti thin films,Thin Solid Films,518, 1180–1184(2009).

[126] A. Z. Sadek, J. G. Partridge, D. G. McCulloch, Y. X. Li, X. F. Yu, W. Wlodarski, K. Kalantar-zadeh, Nanoporous TiO2 thin film based conductometric H2 sensor,Thin Solid Films,518, 1294–1298(2009).

[125] K. Kalantar-Zadeh, A. Z. Sadek, H. Zheng, J. G. Partridge, D. G. McCulloch, Y. X. Li, X. F. Yu, W. Wlodarski, Effect of crystallographic orientation on the anodic formation of nanoscale pores/tubes in TiO2 films,Applied Surface Science,256, 120–123(2009).

[124] Yongxiang Li, Xiaofeng Yu, Qunbao Yang, Fabrication of TiO2 Nanotube Thin Films and Their Gas Sensing Properties, Journal of Sensors, 2009, 402171 (2009).

[123] Xinxin Li, Haitao Yu, Xiaohua Gan, Xiaoyuan Xia, Pengcheng Xu, Jungang Li, Min Liu, Yongxiang Li, Integrated MEMS/NEMS resonant cantilevers for ultra-sensitive biological detection, Journal of Sensors, 2009, 637874 (2009).

[122] 王卓,李永祥,杨群保,无机材料喷墨制备新方法的进展,无机材料学报24,1090–1096 (2009).
 2008

[121] J. T. Zeng, Y. Wang, Y. X. Li, Q. B. Yang, Q. R. Yin, Ferroelectric and Piezoelectric Properties of Tungsten Doped CaBi4Ti4O15 Ceramics, Journal of Electroceramics, 21, 305–308(2008).

[120] Yiqing Lu, Yongxiang Li, Dong Wang, Tianbao Wang, Qingrui Yin, Lead-free Piezoelectric Ceramics of (Bi1/2Na1/2)TiO3-(Bi1/2K1/2)TiO3-(Bi1/2Ag1/2)TiO3 System, Journal of Electroceramics,21, 309–313 (2008).

[119] Y. X. Li, J. T. Zeng, X. Z. Jing, Q. R. Yin, A Novel Technique for Preparation of Grain Oriented BLSF Piezoelectric Ceramics, Journal of Electroceramics, 21, 314–318(2008).

[118] Z. G. Yi, Y. X. Li, J. T. Zeng, Q. B. Yang, Q. R. Yin, Structure and Dielectric Properties of Bi5-xLaxNb3O15 Ceramics, Journal of Electroceramics,21, 319–322(2008).

[117] Y. Wang, Y. X. Li, K. Kalantar-zadeh, T. B. Wang, D. Wang, Q. R. Yin, Effect of Bi3+ ion on piezoelectric properties of KxNa1-xNbO3, Journal of Electroceramics, 21, 629–632(2008).

[116] Z. G. Yi, Y. X. Li, Q. B. Yang, Q. R. Yin, La doping effects on intergrowth Bi2WO6-Bi3TiNbO9 ferroelectrics,Ceramics International,34, 735–739(2008).

[115] M. J. Wu, Y. X. Li, D. Wang, Q. R. Yin, Highly textured (Na1/2Bi1/2)0.94Ba0.06TiO3 ceramics prepared by the screen-printing multilayer grain growth technique,Ceramics International,34, 753–756(2008).

[114 Z. F. Liu, Y. X. Li, Sol–gel synthesis and luminescence property of ZnO:(La,Eu)Cl nanocomposite thin films,Thin Solid Films, 516, 5557–5561(2008).

[113] Z. F. Liu, T. Yamazaki, Y. Shen, T. Kikuta, N. Nakatani, Y. X. Li, O2 and CO sensing of Ga2O3 multiple nanowire gas Sensors,Sens. Actuator B,129, 666–670(2008).

[112] X. F. Yu, Y. X. Li, W. Wlodarski, S. Kandasamy, K. Kalantar-Zadeh, Fabrication of nanostructured TiO2 by anodization: A comparison between electrolytes and substrates,Sens. Actuator B,130, 25–31(2008).

[111] L. J. Ma, Y. X. Li, X. F. Yu, N. F. Zhu, Q. B. Yang, C. H. Noh, Electrochemical preparation of PMeT/TiO2 nanocomposite electrochromic electrodes with enhanced long-term stability,J. Solid State Electrochem.,12, 1503–1509(2008).

[110] L. J. Ma, Y. X. Li, X. F. Yu, Q. B. Yang, C. H. Noh, Using room temperature ionic liquid to fabricate PEDOT/TiO2 nanocomposite electrode-based electrochromic devices with enhanced long-term stability,Sol. Energy Mater. Sol. Cells, 92, 1253–1259(2008).

[109] N. F. Zhu, Y. X. Li, X. F. Yu, Pechinin synthesis and luminescence properties of Y3Ga5O12(YGG):Tb thin film,Materials Letters,62, 2355–2358(2008).

[108] N. F. Zhu, Y. X. Li, X. F. Yu, Luminescence Spectra of YGG:RE3+, Bi3+ (RE = Eu and Tb) and Energy Transfer from Bi3+ to Re3+, Chin. Phys. Lett.,25, 703–706(2008).

[107] H. Z. Song, Y. X. Li, K. Y. Zhao, H. R. Zeng, S. X. Hui, G. R. Li, Q. R. Yin, Contrast mechanism of magnetic domains in electron acoustic imaging,Journal of Applied Physics, 104, 094913 (2008).

[106] H. Z. Song, Y. X. Li, J. T. Zeng, G. R. Li, Q. R. Yin, Observation of magnetic domain structure in Terfenol-D by scanning electron acoustic microscopy,Journal of Magnetism and Magnetic Materials, 320, 978–982(2008).

[105] H. Z. Song, Y. X. Li, H. R. Zeng, L. Ma, G. H. Wu, S. X. Hui, G. R. Li, Q. R. Yin, Electron acoustic imaging of Mn50Ni28Ga22 ferromagnetic shape memory alloy,Applied Physics a-Materials Science & Processing, 92, 309–311 (2008).

[104] S. Kandasamy, M. K. Ghantasala, A. Holland, Y. X. Li, V. Bliznyuk, W. Wlodarski, A. Mitchell, Heat treatment effects on the formation of lanthanum-modified lead zirconate titanate thin films, Materials Letters, 62, 370–373(2008).

[103] H. Zhang, Y. J. Su, L. J. Qiao, W. Y. Chu, D. Wang, Y. X. Li, The Effect of Hydrogen on the Fracture Properties of 0.8(Na1/2Bi1/2)TiO3-0.2(K1/2Bi1/2)TiO3 Ferroelectric Ceramics, Journal of Electronic Materials,37, 368–372(2008).
 专利

[23] 李永祥、马名生、刘志甫、王依琳、吴文俊,一种高热导率低温共烧陶瓷基板材料及其制备方法,中国发明专利申请号:2012100007213 (2012年)。

[22] 李永祥、马名生、刘志甫, 一种低温共烧陶瓷LED基板结构, 中国发明专利申请号:201120257203.0 (2011年)。

[21] 刘志甫、李永祥,陶瓷流延浆料及其制备方法,中国发明专利申请号:201110319794.4(2011)。

[20] 李永祥,王有亮,陆毅青,赵宇,王东,一种铌酸钾钠-铌酸钾锂压电陶瓷及其制备方法,中国发明专利申请号:201010109269.5(2010年)。

[19] 李永祥,伍萌佳,王东,李亚利,惠春,织构化铌酸钾钠基无铅压电陶瓷的制备方法,中国发明专利申请号:201010192665.9(2010年)。

[18] 李永祥,卢志远,王依琳,吴文骏,织构化锂铌钛(Li-Nb-Ti-O)微波介质陶瓷及其制备方法,中国发明专利申请号:201010537668.1(2010年)。

[17] 李永祥,卢志远,王依琳,吴文骏,片状锂-铌-钛(Li-Nb-Ti-O)模板晶粒及其制备方法,中国发明专利申请号:201010537689.3(2010年)。

[16] 李永祥,李正法,一种次晶有序排列的铌酸盐无铅压电陶瓷及其制备方法,中国发明专利号:ZL 200910046970.4(2009年)。

[15] 李永祥,龙艳平,王依琳,吴文骏,降低锂-铌-钛系微波介质陶瓷烧结温度的方法,中国发明专利申请号:200910049374.1(2009年)。

[14] 李永祥,王卓,朱南飞,王东,一种导电线路的制作方法,中国发明专利号:ZL 200810033433.1(2008年)。

[13] 李永祥,伍萌佳,一种片状钛酸铋钠模板晶粒及其制备方法,中国发明专利申请号:200810034763.2(2008年)。

[12] 李永祥,王卓,王东,制备组合材料芯片的方法及所使用的电磁喷射系统,中国发明专利申请号:200810042322.7(2008年)。

[11] 王依琳,吴文骏,赵梅瑜,李永祥,蔡聪麟,沢崎章,提高Li-Nb-Ti基微波介质陶瓷绝缘电阻率的方法,中国发明专利申请号:200810205225.5(2008年)。

[10] 李永祥,伍萌佳,杨群保,一种钛酸铋钠-钛酸钡无铅压电陶瓷及其制备方法,中国发明专利号:ZL 200610119423.0(2006年)。

[9] 李永祥,葛万银,一种无机-有机复合溶液型电致变色材料及器件和制备方法,中国发明专利号:ZL 200510112409.3(2005年)。

[8] 王依琳,吴文骏,赵梅瑜,李蔚,提高与铜共烧的含钛微波介质陶瓷绝缘电阻率的方法,中国发明专利号:ZL 200510026991.1(2005年)。

[7] 李永祥,王东,徐志华,镓酸钇基红、绿、兰三色荧光粉,中国发明专利号:ZL 200410025792.4(2004年)。

[6] 李永祥,荆学珍, 曾江涛,殷庆瑞,丝网印刷制备织构化钛酸铋钠钾压电陶瓷的工艺,中国发明专利号:ZL 200410017305.X(2004年)。

[5] 李永祥,曾江涛,荆学珍,无模板丝网印刷制备织构化铋层状压电陶瓷的工艺,中国发明专利号:ZL 200410017306.4(2004年)。

[4] 王东,李永祥,陆毅青,王天宝,殷庆瑞,小功率超声换能器用掺杂改性钛酸铋钠钡压电陶瓷及其制备方法,中国发明专利号:ZL 200410017307.9(2004年)。

[3] 王东,李永祥,陆毅青,王天宝,殷庆瑞,一种掺杂改性钛酸铋钠钾压电陶瓷及其制备方法,中国发明专利号:ZL 200410017308.3(2004年)。

[2] 杨群保,李永祥,殷庆瑞,王佩玲,一种新型钛酸钾的组成和制备方法,中国发明专利号:ZL 03129114.7(2003年)。

[1] 杨群保,李永祥,殷庆瑞,王佩玲,形貌可控的氧化铋粉体的制备新方法,中国发明专利号:ZL 03151466.9(2003年)。
 会议报告

[20]李永祥, “Textured Electroceramics by screen-printing templated grain growth (sp-RTGG) processing”, 7th SRK,Pusan National University, Busan, Korea,  2011-11-11(中日韩先进无机材料研讨会)。

[19] 刘志甫, “Nanostructures for advanced gas sensors”, 第一届中意双边材料研讨会(ICBFMS-1),2011年11月,中国上海。

[18] 李永祥, “Textured Li-Nb-Ti-O System microwave ceramics with continuously tunable dielectric properties”,12th Eurropean  Meeting on  Ferrroelectricity,  June 26th – July 1st  2011, Bordeaux, France。

[17] 马名生, “Thermal performance of high power LED package based on LTCC”, The 12th International Conference on Electronic Packaging Technology &High Density Packaging (ICEPT-HDP 2011),2011年8月,中国上海。

[16] 李永祥,“Textured Pb-free piezoelectric ceramics by screen-printing reactive templated grain growth (sp-RTGG)”,ECerS XII,12th Conference of the European Ceramic Society,2011年6月19-23日,瑞典斯德哥尔摩。

[15] 李永祥,“具有可调介电常数的织构化锂铌钛微波介质陶瓷”,第十三届全国电介质物理、材料与应用学术会议,2010年11月25-27日,中国成都。

[14] 李永祥,“Ferroelectric, piezoelectric properties of Aurivillius phase intergrowth ferroelectrics and the underlying materials design”,The 6th SIC-RCDAMP-KIT Joint Workshop on Advanced Inorganic Materials,2010年10月21日,日本京都。

[13] 李永祥,“Piezoelectric properties of KLN modified (K0.48Na0.52)NbO3 lead-free piezoceramics”,The 2nd China-Japan Symposium on Ferroelectric Materials and Their Applications,2010年10月15日,日本富山。

[12] 李永祥,“Structure Transformation from Aurivillius to Perovskite”,the 7th Asian Meeting on Ferroelectricity and the 7th Asian Meeting on Electroceramics (AMF-AMEC-2010),2010年6月28日,韩国济州。

[11] 李永祥,“Phase structure, dielectric, and piezoelectric properties of potassium lithium niobate (KLN) modified (K0.48Na0.52)NbO3 lead-free piezoceramics”,Ceramic Interconnect and Ceramic Microsystems Technology (CICMT) Conference,2010年4月18日,日本千叶。

[10] 李永祥,“Structure design and properties enhancement of layer-structured perovskite ferroelectrics”,Joint Meeting of 12th International Meeting on Ferroelectricity (IMF-12) & 18th IEEE International Symposium on the Applications of Ferroelectrics (ISAF-18),2009年8月23-27日,中国西安。

[9]  李永祥(特邀报告)“压电陶瓷的晶粒尺寸与性能关系探讨”2008第十二届全国电介质物理、材料与应用学术会议,2008年4月西安;

[8]  李永祥(特邀报告): “Effect of local stress on microstructures of some ferroic materials”2008重庆中美材料国际研讨会, 6月9-12日中国重庆;

[7]  李永祥(特邀报告):应邀参加第六届亚洲电子陶瓷会议,并做题为“钛酸铋钠基无铅压电陶瓷织构化”研究的特邀报告, 2008年10月22日,日本筑波。

[6] 李永祥(特邀报告): The China International Conference on High-Performance Ceramics (CICC-5) 2007. 05 Changsha, China

[5]李永祥(特邀报告),5th Asian Meeting on Electroceramics, 2006. 12 Bangkok, THAILAND

[4] Yongxiang Li, Jiangtao Zeng, Qingrui Yin, “Electrical property improvement of CaBi4Ti4O15 ceramics by dopants and grain orientation,” 6th Pacific Rim Conference on Ceramic and Glass Technology, September 11-16, 2005 Maui, USA. (Invited Talk)

[3] Y. X. Li, The current progress of lead-free piezoelectric ceramics in China Sino-German Symposium on New Generation Polar Oxide Materials and Devices,March 1-5, 2005 Xi’an, China (Invited Talk)

[2] Li Yong Xiang, Current progress on lead-free piezoelectric ceramics, The 1st K-J-C Joint Workshop, Oct. 14-17. 2005, Busan, Korea (Workshop Chair)

[1] Yongxiang Li, Jiangtao Zeng, Xuezhen Jing & Qingrui Yin, “A Novel Technique for Preparation of Grain Oriented BLSF Piezoelectric Ceramics,” AMEC-4 4th Asian Meeting on Electroceramics, June 27–30, 2005, Hangzhou, China (Session Chair)
 成果奖励

(1)2005上海市优秀学位论文(徐志华)

(2)2006上海市优秀毕业生(易志国)

(3)2007年上海-应用材料研究与发展基金AM奖学金(于晓峰)

(3)2007年度上海硅酸盐研究所质量奖(课题组)。

(4)2008年上海-应用材料研究与发展基金AM奖学金(宋红章)

(5)2008 Excellent Poster Award of MRS International Materials Research Conference(王卓)

(6)2008 上海市优秀毕业生(马隆建)

(7)2008年宝钢教育基金"优秀学生奖"(宋红章)

(8)2008年度优秀导师(李永祥)。

(9)2009 上海市优秀毕业生(宋红章)

(10)获得澳大利亚政府(The Australian Agency for International Development, AusAID) 的Australian Leadership Awards Fellowships.

(11)李永祥2010年度上海市科委优秀学科带头人

(12)博士生郭腾第七届亚洲电子陶瓷国际会议和亚洲铁电学国际会议Excellent Poster Awards (Second Price) (The 7th AMF-AMEC-2010 Conference, June 28th ~ July 1st; Jeju Island, Republic of Korea).

(13)马名生获中国科学院"三好学生"荣誉称号(2010年)。

(14)马名生获中国科学院"三好学生"荣誉称号(2011年度)。

(15)国际合作伙伴计划"新一代高性能压电材料及其应用基础研究"创新团队获得上海硅酸盐研究所2011年度合作特别奖。 仪器设备

    

      陶瓷材料工艺设备

      高温烧结炉(1450oC)  10台

      高温烧结炉(1700oC)  1台

      微波烧结炉(1600oC)  1台

      管式气氛炉(1400oC) 1台

      玻璃熔炉   (1700oC)  1台

      鼓风干燥箱          6台

      行星式高能球磨机    1台

      卧式砂磨机          1台

      滚筒式球磨机        2台

      喷雾干燥机          1台

      线切割机            1台

      磨片机              1台

 

      LTCC      工艺设备

      流延机        1台

      打孔机         1台

      丝网印刷机     1台

      填孔机         1台

      温水静压机     1台

      脱泡机         1台

 

      表征测试设备

      LCR测试系统

      网络分析仪

      阻抗分析仪

      介电温谱测试系统

      压电陶瓷极化装置

      d33 测试仪

      高低温试验箱

      电化学工作站

      样品检查显微镜

      荧光光谱测试仪

其它研究工作条件

    本实验室还拥有50平米1000级超净室,主要用于LTCC工艺及相关集成器件研究;拥有8核工作站1台用于热场、电磁场模拟及器件设计、材料模拟计算等;上海硅酸盐所分析测试中心拥有无机材料物相、微结构、化学组成、热物性等完备的分析测试设备,这些公共设备为相关课题的研究提供了重要支撑。
 

相关话题/导师