李敬锋
近期热点
资料介绍
个人简历
教育背景\r1980.09-1984.07 华中科技大学机械工程2系金属材料及热处理专业学士学位\r1985.10-1991.03 日本东北大学(Tohoku University)工学部材料系,工学硕士(1988.3), 工学博士(1991.3)\r\r工作履历\r2002.2-现在 清华大学材料学院教授、博士生导师\r(2005-2012年任材料科学与工程系副主任,2012-2016年任材料学院副院长)\r1997.4-2002.9 日本东北大学工学部材料系副教授\r1992.3-1997.3 日本东北大学工学部材料系助理教授\r1991.3-1992.2 日本陶瓷技术(Nihon Ceratec)公司留学博士后特别研究人员\r\r学术兼职\r《Journal of Materiomics》主编,《硅酸盐学报》副主编,《NPG Asia Materials》顾问编委,《Journal of Advanced Ceramics》、《Journal of Asia Ceramic Societies》、《Rare Metals》、《Materials Today Physics》、《Energy Harvesting and Systems》、《粉末冶金技术》编委、2008年至2013年曾担任《Journal of Materials Processing Technology》副主编(Subject Editor);国际梯度功能材料顾问委员会理事,IEEE-TUFFC ferroelectric committee 委员,中国硅酸盐学会理事,中国硅酸盐学会薄膜与涂层分会副理事长,中国微米纳米技术学会理事,中国材料研究学会理事,中国材料研究学会热电材料与应用分会副主任委员,中国金属学会粉末冶金分会第六届委员会委员。\r\r奖励与荣誉\r2022年,日本工程院外籍院士\r2021年,日本东北大学特任教授(客座)\r2020年,美国陶瓷学会Fellow\r2019年,2019度中国建筑材料联合会-中国硅酸盐学会建筑材料科学技术奖(基础研究类)一等奖\r2019年,国际热电学会理事\r2019年,烧结科学国际学会Full Member\r2019年度«中国科学»«科学通报»优秀作者\r2014年获Journal of the American Ceramic Society Author Loyalty Recognition Award\r2012年获2011年度北京市科学技术奖三等奖(高性能纳米复合结构热电材料与微器件技术)\r2012年获2010年度北京市科学技术奖三等奖(高性能铌酸钾钠基无铅压电陶瓷的研发)\r2008年入选教育部长江学者特聘教授\r2003年获国家杰出青年基金\r1995年获日本金属学会青年研究者奖\r1998年获日本原田研究奖研究领域
"""""压电陶瓷与器件,热电材料与器件,MEMS材料技术,陶瓷复合材料及其力学性能;无铅压电陶瓷,压电陶瓷薄膜与MEMS微结构,压电复合材料,高性能热电半导体及其MEMS微型热电器件,功能梯度材料,复合陶瓷的强韧性,压电陶瓷的力学性能"近期论文
Review Articles:\r\rJ. Roedel, J.-F. Li, Lead-free piezoceramics: Status and perspectives, MRS Bulletin, 43(2018)576-580.\r\rJ.-F. Li, K. Wang, F.-Y. Zhu, L.-Q. Cheng and F.-Z. Yao, (K, Na)NbO3-Based Lead-Free Piezoceramics: Fundamental Aspects, Processing Technologies and Remaining Challenges, Journal of the American Ceramic Society, 96 (2013)3677-3696. (Feature/Review article, cover page)\r\rJ.-F. Li, W. S. Liu, L.-D. Zhao, M. Zhou, High-performance nanostructured thermoelectric materials, NPG Asia Materials, 2 (2010) 152-158. (Review).\r\rJ.-F. Li, Y. Pan, C.-F. Wu, F.-H. Sun, T.-R. Wei, Processing of advanced thermoelectric materials, Science China Technological Science, 60(2017)1347. (Review)\r\rSelected Research papers (for a complete set of publications, please visit http://www.researcherid.com/rid/D-2770-2014):\r\rB. C. Qin, D. Y. Wang, X. X. Liu, Y. X. Qin, J.-F. Dong, J. F. Luo, J.-W. Li, W. Liu, G. J. Tan, X. F. Tang, J.-F. Li, J. Q. He, L.-D. Zhao, Power generation and thermoelectric cooling enabled by momentum and energy multiband alignments, Science, 373(2021) 556.\r\rH. H. Hu. H. L. Zhuang, Y. L. Jiang, J. L. Shi, J.-W. Li, B. W. Cai, Z. R. Han, J. Pei, B. Su, Z.-H. Ge, B.-P. Zhang, J.-F. Li, Thermoelectric Cu12Sb4S13-Based Synthetic Minerals\r\rwith a Sublimation-Derived Porous Network, Advanced Materials, 33(2021)2103633\r\rH. L. Zhuang, J. Pei, B. W. Cai, J. F. Dong, H. H. Hu, F. H. Sun, Y. Pan, G. J. Snyder, J.-F. Li, Thermoelectric Performance Enhancement in BiSbTe Alloy by Microstructure Modulation via Cyclic Spark Plasma Sintering with Liquid Phase, Advanced Functional Materials, 31(2021) 2009681.\r\rL. S. Liu, K. Xu, Q. Li, J. Daniels, H. Zhou, J. Y. Li, J. Zhu, J. Seidel, J.-F. Li, Giant Domain Wall Conductivity in Self-Assembled BiFeO3 Nanocrystals, Advanced Functional Materials, 31(2021)2005876\r\rQ. Liu, Y. C. Zhang, J. Gao, Z. Zhou, D. Yang, K.-Y. Lee, A. Studer, M. Hinterstein, K. Wang, X. W. Zhang, L. T. Li, J.-F. Li, Practical high-performance lead-free piezoelectrics: structural Flexibility beyond utilizing multiphase coexistence, National Science Review, 7(2020)355-365.\r\rJ. Pei, B. W. Cai, H.-L. Zhuang, J.-F. Li, Bi2Te3-based applied thermoelectric materials: research advances and new challenges, National Science Review, 7(2020)1856-1858.\r\rW. He, D. Y. Wang, H. J. Wu, Y. Xiao, Y. Zhang, D. S. He, Y. Feng, Y.-J. Hao, J.-F. Dong, R. Chetty, L. J. Hao, D. F. Chen, J. F. Qin, Q. Yang, X. Li, J.-M. Song, Y. Zhu, W. Xu, C. Niu, X. Li, G. Wang, C. Lin, M. Ohta, S. J. Pennycook, J. Q. He, J.-F. Li, L.-D. Zhao, High thermoelectric performance in low-cost SnS0.91Se0.09 crystals, Science, 365[6460](2019) 1418\r\rY. Pan, Y. Qiu, I. Witting, I. T. Witting, L. G. Zhang, C. G. Fu, J.-W. Li, Y. Huang, F.-H. Sun, J. Q. He, G. J. Snyder, C. Felser, J.-F. Li, Synergistic modulation of mobility and thermal conductivity in (Bi,Sb)2Te3 towards high thermoelectric performance, Energy & Environmental Science, 12(2019)624-630.\r\rJ. F. Dong, F.-H. Sun, H. C. Tang, J. Pei, H.-L. Zhuang, H.-H. Hu, B.-P. Zhang, Y. Pan, J.-F. Li, Medium-temperature thermoelectric GeTe: vacancy suppression and band structure engineering leading to high performance, Energy & Environmental Science, 12(2019)1396-1403.\r\rC. Chang, M. Wu, D. He, Y. Pei, C.-F. Wu, X. Wu, H.L. Yu, F.Y. Zhu, K. D. Wang, Y. Chen, L. Huang, J.-F. Li, J. Q. He, L.-D. Zhao, 3D charge and 2D phonon transports leading to extremely high out-of-plane ZT in n-type SnSe crystals, Science, 360(2018)778-783.\r\rQ. Liu, Y. Zhang, J. Gao, Z. Zhou, H. Wang, K. Wang, X. W. Zhang, L. T. Li, and J.-F. Li, High-Performance Lead-free Piezoelectrics with Local Structural Heterogeneity, Energy & Environmental Science, 11(2018)3531-3539.\r\rY. Pan, U. Aydemir, J. A. Grovogui, I. T. Witting, R. Hanus, Y. Xu, J. Wu, C.-F. Wu, F.-H. Sun, H.-L. Zhuang, J.-F. Dong, J.-F. Li, V. P. Dravid, G. J. Snyder, Melt-Centrifuged (Bi,Sb)2Te3: Engineering Microstructure toward High Thermoelectric Efficiency, Advanced Materials, 30(2018)1802016.\r\rH. C. Tang, F.-H. Sun, J.-F. Dong, Asfandiyar, H.-L. Zhuang, Y. Pan, J.-F. Li, Graphene network in copper sulfide leading to enhanced thermoelectric properties and thermal stability, Nano Energy, 49(2018)267-273.\r\rW., Wei, C. Chang, T. Yang, J. Liu, H. C. Tang, J. Zhang, Y. S. Li, Feng Xu, Z. D. Zhang, J.-F. Li, G. D. Tang, Achieving High Thermoelectric Figure of Merit in Polycrystalline SnSe via Introducing Sn Vacancies, Journal of the American Chemical Society, 140(2018) 499-505.\r\rQ. Liu, J.-F. Li, L. Zhao, Y. C. Zhang, J. Gao, W. Sun, K. Wang, L. T. Li, Niobate-based lead-free piezoceramics: a diffused phase transition boundary leading to temperature-insensitive high piezoelectric voltage coefficients, Journal of Materials Chemistry C, 6(2018)1116-1125.\r\rL. Zhao, Q. Liu, J. Gao, S. J. Zhang, J.-F. Li, Lead-Free Antiferroelectric Silver Niobate Tantalate with High Energy Storage Performance, Advanced Materials, 29(2017)1701824.\r\rM.-H. Zhang, K. Wang, Y.-J. Du, G. Dai, W. Sun, G. Li, D. Hu, H. C. Thong, C. L. Zhao, X.-Q. Xi, Z.-X. Yue, J.-F. Li, High and Temperature-Insensitive Piezoelectric Strain in Alkali Niobate Lead-free Perovskite, Journal of the American Chemical Society, 139(2017) 3889-3895.\r\rC.-F. Wu, T.-R. Wei, F.-H. Sun and J.-F. Li, Nanoporous PbSe–SiO2 Thermoelectric Composites, Advanced Science, 4(2017)1700199\r\rY. Pan, U.t Aydemir, F.-H. Sun, C.-F. Wu, T. C. Chasapis, G. J. Snyder and J.-F. Li, Self-Tuning n-Type Bi2(Te,Se)3/SiC Thermoelectric Nanocomposites to Realize High Performances up to 300 °C, Advanced Science, 4(2017)1700259.\r\rJ. Luo, W. Sun, Z. Zhou, H.-Y. Lee, K. Wang, F. Y. Zhu, Y. Bai, Z. J. Wang and J.-F. Li, Monoclinic (K,Na)NbO3 Ferroelectric Phase in Epitaxial Films, Advanced Electronic Materials, 3(2017) 1700226 (cover page)\r\rZ. L. Li, J.-F. Dong, F.-H. Sun, S. Hirono, J.-F. Li, Significant Enhancement of the Thermoelectric Performance of Higher Manganese Silicide by Incorporating MnTe Nanophase Derived from Te Nanowire, Chemistry of Materials, 29(2017)7378.\r\rF.-Z. Yao, K. Wang, W. Jo, K. G. Webber, T. P. Comyn, J.-X. Ding, B. Xu, L.-Q. Cheng, M.-P. Zheng, Y.-D. Hou, J.-F. Li, Diffused phase transition boosts thermal stability of high-performance lead-free piezoelectrics, Advanced Functional Materials, 26(2016)1217-1224.\r\rT.-R. Wei, G. Tan, X. Zhang, C.-F. Wu, J.-F. Li, V. P. Dravid, G. J. Snyder, M. G. Kanatzidis, Distinct Impact of Alkali-Ion Doping on Electrical Transport Properties of Thermoelectric p-type Polycrystalline SnSe, Journal of the American Chemical Society, 138(2016)8875-8882.\r\rY. Pan, J.-F. Li, Thermoelectric performance enhancement in n-type Bi2(TeSe)3 alloys owing to nanoscale inhomogeneity combined with a spark plasma textured-microstructure, NPG Asia Materials, 8(2016)e275.\r\rW. Sun, J.-F. Li, Q. Yu, L.-Q. Cheng, Phase transition and piezoelectricity of sol-gel-processed Sm-doped BiFeO3 thin films on Pt(111)/Ti/SiO2/Si substrates, Journal of Materials Chemistry C, 3 (2015)2115-2122.\r\rY. Pan, T.-R. Wei,C.-F. Wu, J.-F. Li, Electrical and thermal transport properties of spark plasma sintered n-type Bi2Te3-xSex alloys: combined effect of point defect and Se content, Journal of Materials Chemistry C, 2(2015)17302-17306.\r\rD. Wu, L.-D. Zhao, X. Tong, W. Li, L. J. Wu, Q. Tan, Y. L. Pei, L. Huang, J.-F. Li, Y. M. Zhu, M. G. Kanatzidis, J. G. He, JQ, Superior thermoelectric performance in PbTe-PbS pseudo-binary: extremely low thermal conductivity and modulated carrier concentration, Energy & Environmental Science, 8(2015) 2056-2068.\r\rL.-D. Zhao, J. Q. He, D. Berardan, Y.-H. Lin, J.-F. Li, C.-W. Nan, N. Dragoe, BiCuSeO oxyselenides: new promising thermoelectric materials, Energy & Environmental Science, 7(2014)2900-2924\r\rZ.-Y. Li and J.-F. Li, Fine-Grained and Nanostructured AgPbmSbTem+2 Alloys with High Thermoelectric Figure of Merit at Medium Temperature, Advanced Energy Materials, 4(2014)1300937.\r\rQ. Tan, L-D. Zhao, J.-F. Li, C.-F. Wu, T.-R. Wei, Z.-B. Xing, M. G. Kanatzidis, Thermoelectrics with earth abundant elements: low thermal conductivity and high thermopower in doped SnS, Journal of Materials Chemistry A, 2(2014)17302-17306.\r\rT.-R. Wei, H. Wang, Z. M. Gibbs, C.-F. Wu, G. J. Snyder, J.-F. Li, Thermoelectric properties of Sn-doped p-type Cu3SbSe4: a compound with large effective mass and small band gap, Journal of Materials Chemistry A, 2(2014)13527-13533.\r\rL.-Q. Cheng, K. Wang, J.-F. Li, Y. M. Liu, J. Y. Li, Piezoelectricity of lead-free (K, Na)NbO3 nanoscale single crystals, Journal of Materials Chemistry C, 2(2014)9091-9098. (Front cover article).\r\rQ. Yu, J.-F. Li, F.-Y. Zhu, J.-Y. Li, Domain evolution of tetragonal Pb(ZrxTi1-x) O-3 piezoelectric thin films on SrTiO3 (100) surfaces: combined effects of misfit strain and Zr/Ti ratio, Journal of Materials Chemistry C, 2(2014)5836-5841.\r\rK. Wang, F.-Z. Yao, W. Jo, D. Gobeljic, V. V. Shvartsman, D. C. Lupascu, J.-F. Li, J. Rodel, Temperature-Insensitive (K, Na)NbO3-Based Lead-free Piezoactuator Ceramics, Advanced Functional Materials, 23, 4079-4086 (2013)\r\rJ. H. Li, Q. Tan, J.-F. Li, et. al., BiSbTe-Based Nanocomposites with High ZT: The SiC Nanodispersion on Thermoelectric Properties, Advanced Functional Materials, 23 (2013) 4317-4323.\r\rF. Li, J.-F. Li, L.-D. Zhao, K. Xiang, Y. Liu, B.-P. Zhang, Y.-H. Lin, C.-W. Nan, H.-M. Zhu, Polycrystalline BiCuSeO oxide as a potential thermoelectric material, Energy & Environmental Science, 5 (2012) 7188-7195.\r\rY. Xu, Q. Yu, J.-F. Li, A facile method to fabricate vertically aligned (K, Na)NbO3 lead-free piezoelectric nanorods, Journal of Materials Chemistry, 22(2012)23221.\r\rY. Liu, L.-D. Zhao, Y. Liu, J. Lan, W. Xu, F. Li, B.-P. Zhang, D. Berardan, N. Dragoe, Y.-H. Lin, C.-W. Nan, J.-F. Li, and H. Zhu, Remarkable Enhancement in Thermoelectric Performance of BiCuSeO by Cu Deficiencies, Journal of the American Chemical Society, 133, (2011) 20112-20115\r\rD.-W. Liu, J.-F. Li, Microfabrication of thermoelectric modules by patterned electrodeposition using a multi-channel glass template, Journal of Solid State Electrochemistry, 15[3] 479-484 (2011).\r\rJ.-F. Li, Z.-X. Zhu, and F.-P. Lai, Thickness-Dependent Phase Transition and Piezoelectric Response in Textured Nb-Doped Pb(Zr0.52Ti0.48)O3 Thin Films, J. Phys. Chem. C, 114, 41, (2010)17796-17801.\r\rK. Wang, J.-F. Li, Domain Engineering of Lead-free Li-modified (K, Na)NbO3 Polycrystals with Highly Enhanced Piezoelectricity, Advanced Functional Materials, 20(2010) 1924-1929.\r\rZ.-X. Zhu, J.-F. Li, Y. Y. Liu, J. Y. Li, Shifting of morphotropic phase boundary and superior piezoelectric response in Nb-doped Pb(Zr,Ti)O3 epitaxial thin films, Acta Materialia, 57 (2009) 4288–4295.\r\rM. Zhou, J.-F. Li, T. Kita, Nanostructured AgPbmSbTem+2 system bulk materials with enhanced thermoelectric performance, Journal of the American Chemical Society, 130 (2008) 4527-4532.\r\rK. Wang, J.-F. Li, Analysis of crystallographic evolution in (Na,K)NbO3-based lead-free piezoceramics by x-ray diffraction, Applied Physics Letters, 91(2007) 262902.\r\rJ.-F. Li, K. Wang, B. P. Zhang, L. M. Zhang, Ferroelectric and piezoelectric properties of fine-grained Na0.5K0.5NbO3 lead-free piezoelectric ceramics prepared by spark plasma sintering, Journal of the American Ceramic Society 89 (2006) 706.\r\rH. Wang, J.-F. Li, C.-W. Nan, M. Zhou, W.S. Liu, B.-P. Zhang and T. Kita, High-Performance Ag0.8Pb18+xSbTe20 thermoelectric bulk materials fabricated by mechanical alloying and spark plasma sintering, Applied Physics Letters, 88 (9) 092104 (2006).\r\rJ.-F. Li, K. Wang, B. P. Zhang, L. M. Zhang, Ferroelectric and piezoelectric properties of fine-grained Na0.5K0.5NbO3 lead-free piezoelectric ceramics prepared by spark plasma sintering, Journal of the American Ceramic Society 89 (2006) 706-709.\r\rY. H. Zhen, J.-F. Li, Normal sintering of (K,Na)NbO3-based ceramics: Influence of sintering temperature on densification, microstructure, and electrical properties, Journal of the American Ceramic Society, 89 (2006)3669-3675\r\rW. Gong, J.-F. Li, C.-E Peng, Z. Gui and L. T. Li, In-Plane Aligned Pb(Zr, Ti)O3 Microbelts Fabricated by Near Migration and Restricted Growth, Advanced Materials, 17 (2005)1952-1956.\r\rW. Gong, J.-F. Li*, X. C. Chu, Z. L. Gui and L. T. Li , Combined effect of preferential orientation and Zr/Ti atomic ratio on electrical properties of Pb(ZrxTi1-x)O3 thin films, Journal of Applied Physics, 96 [1](2004) 590-595.\r\rJ.-F. Li, S. Tanaka, T. Umeki, S. Sugimoto, M. Esashi, R. Watanabe, Microfabrication of Thermoelectric Microdevices by Silicon Molding Process, SENSORS AND ACTUATORS A-PHYSICAL 108 (2003)97-102.\r\rJ.-F. Li, K. Takagi, N. Terakubo, R. Watanabe, Electrical and mechanical properties of piezoelectric ceramic/metal composites in the Pb(Zr,Ti)O3/Pt system, Applied Physics Letters, 79, (2001)2441-2443.\r\rJ.-F. Li, W. Pan, F. Sato, R. Watanabe, Mechanical Properties of Polycrystalline Ti3SiC2 at Ambient and Elevated Temperatures, Acta Materialia, 49,937-945 (2001).\r\rS. Wang, J.-F. Li, K. Wakabayashi, M. Esashi, R. Watanabe, Lost Silicon Mold Process for PZT Microstructures, Advanced Materials 11 (1999)873-876 相关热点
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