姓 名
唐新峰
性 别
男
民 族
汉
出生年月
1962-08

职 称
首席教授
职 务

联系电话
**

单位名称
材料复合新技术国家重点实验室
Email
tangxf@whut.edu.cn

实验室网址
http://sklwut.whut.edu.cn/yjfx/201406/t**_117748.htm

研究方向
1.热电材料电热输运机制及高性能热电材料开发
2.高效新型热电器件的研发和应用技术研究
3.纳米和梯度功能材料研究

教育背景
?1979.09~1983.07 大连交通大学（原大连铁道学院）金属材料专业（获学士学位）
?1985.09~1988.05 西南交通大学 金属材料专业 （获硕士学位）
?1997.09~2000.10 日本东北大学 材料物性专业（获工学博士学位）

工作经历
?1983.08~1985.08西南交通大学材料科学与工程系助教
?1988.06~1997.08 武汉工业大学材料复合新技术国家重点实验室讲师﹑副教授
?1997.09~2001.03 日本东北大学金属材料研究所客座研究员、助手
?2001.04~2011.08 武汉理工大学材料复合新技术国家重点实验室教授
?2001.07~2011.08 同上博士生导师
?2009.10~2010.04 美国密歇根大学物理系访问****
?2011.09~至今武汉理工大学材料学科首席教授、博士生导师

项目情况
?高构型熵热电化合物设计和结构调控及电热输运机制研究（**），国家自然科学基金面上项目，80万元，项目负责人
?复合热电材料界面调控与电热输运（**），国家自然科学基金重点项目，350万元，项目负责人
?面向规模化应用的高性能热电材料快速非平衡制备（2013CB632502），国家973重大基础研究课题子课题，800万元，项目负责人
?汽车尾气热电发电回收利用关键技术及其示范轿车合作研究开发（No. 2011DFB60150），中美清洁能源合作项目，918万元，项目负责人
?掺杂局域共振态效应结合原位相分离纳米结构提高Mg₂Si_1-xSn_x基材料热电性能（**），国家自然科学基金面上项目，60万元，项目负责人
?热电材料结构低维化与性能（2007CB607501），国家973重大基础研究课题子课题，570万元，项目负责人

代表性学术
成果

唐新峰教授，博士生导师，于2000年获得日本东北大学工学博士。现任武汉理工大学首席教授、中国热电学会副理事长、美国物理学会会士，曾担任国际热电学会理事会理事（2014~2017）。
唐新峰教授的主要研究方向为高性能热电材料、器件及应用技术。近几年来，在热电研究领域承担了科技部中美重大国际合作项目专项、国家“973”重点基础研究课题、国家“863”高技术项目、国家自然科学基金项目等各类项目。唐新峰教授长期从事热电材料的研究，在热电材料领域开展了系统和创新性的研究工作。发现了Mg₂Si_1-xSn_x体系的能带结构收敛效应；发展了MS-SPS快速非平衡制备多尺度热电材料的新技术；发现了热电材料的自蔓延燃烧合成（SHS）现象，提出了材料发生自蔓延燃烧合成反应的普适热力学新判据，突破和颠覆了传统热力学经验判据，发展了SHS-3D打印热电材料和器件超快速集成制造新技术；与合作者一起开发出100 kW级太阳能热电-光电复合发电系统和千瓦级汽车尾气热电发电示范车。
研究工作在Nature Communications、Science Advances、Physical Review Letters、Physical Review B、Nano Letters、Journal of American Chemical Society、Advanced Materials、Energy Environmental Science、Advanced Energy Materials、Chemistry of Materials、Journal of Materials Chemistry、Acta Materialia、Applied Physics Letters 等国内外重要期刊上系统发表学术论文200 余篇，获授权发明专利50余件。获国家自然科学二等奖、国家技术发明二等奖、教育部技术发明一等奖等奖励。指导的学生有3 人获国际热电学会授予的GoldsmidAward，该奖在全世界范围内每年只授予一名博士，指导的博士生有2 人获全国百篇优秀博士论文提名、4 人获湖北省优秀博士学位论文。2015 年当选美国物理学会会士（APS Fellow）。
代表性论文如下：
1.Rigui Deng, Xianli Su, Shiqiang Hao, Zheng Zheng, Min Zhang, Hongyao Xie, Wei Liu, Yonggao Yan, Chris Wolverton, Ctirad Uher, Mercouri G. Kanatzidis and Xinfeng Tang. High thermoelectric performance in Bi_0.46Sb_1.54Te₃nanostructured with ZnTe.Energy & Environmental Science,11(2018), 1520-1535.
2.Zheng Zheng, Xianli Su, Rigui Deng, Constantinos Stoumpos, Hongyao Xie, Wei Liu, Yonggao Yan, Shiqiang Hao, Ctirad Uher, Chris Wolverton, Mercouri G. Kanatzidis and Xinfeng Tang. Rhombohedral to Cubic Conversion of GeTe via MnTe Alloying Leads to Ultralow Thermal Conductivity, Electronic Band Convergence, and High Thermoelectric Performance,Journal of the American Chemical Society,140.7(2018), 2673-2686.
3.Rigui Deng, Xianli Su, Zheng Zheng, Wei Liu, Yonggao Yan, Qingjie Zhang, Vinayak P Dravid, Ctirad Uher, Mercouri G Kanatzidis, Xinfeng Tang, Thermal conductivity in Bi0. 5Sb1. 5Te3+ x and the role of dense dislocation arrays at grain boundaries, Science Advances, 2018, 4(6), eaar5606.
4.Yonghui You, Xianli Su, Shiqiang Hao, Wei Liu, Yonggao Yan, Tingting Zhang, Min Zhang, Chris Wolverton, Mercouri G Kanatzidis, Xinfeng Tang, Ni and Se co-doping increases the power factor and thermoelectric performance of CoSbS, J. Mater. Chem. A, 2018, 6, 15123-15131.
5.Gang Zheng, Xianli Su, Hongyao Xie, Yuejiao Shu, Tao Liang, Xiaoyu She, Wei Liu, Yonggao Yan, Qingjie Zhang, Ctirad Uher, Mercouri G. Kanatzidis and Xinfeng Tang. High thermoelectric performance of p-BiSbTe compounds prepared by ultra-fast thermally induced reaction,Energy & Environmental Science,10(2017), 2638-2652.
6.Tao Liang, Xianli Su, Yonggao Yan, Gang Zheng, Xiaoyu She, Yonghui You, Ctirad Uher, Mercouri G. Kanatzidis and Xinfeng Tang. Panoscopic approach for high-performance Te-doped skutterudite, NPG Asia Materials, 9(2017), e352.
7.Xianli Su, Ping Wei, Han Li, Wei Liu, Yonggao Yan, Peng Li, Chuqi Su, Changjun Xie, Wenyu Zhao, Pengcheng Zhai, Qingjie Zhang, Xinfeng Tangand Ctirad Uher. Multi-Scale Microstructural Thermoelectric Materials:Transport Behavior, Non-Equilibrium Preparation, and Applications, Advanced Materials, 29.20(2017), **.
8.Hongyao Xie, Xianli Su, Yonggao Yan, Wei Liu, Liangjun Chen, Jiefei Fu, Jihui Yang, Ctirad Uher and Xinfeng Tang. Thermoelectric performance of CuFeS_2+2xcomposites prepared by rapid thermal explosion, NPG Asia Materials, 9(2017), e390.
9.Wei Liu, Kang Yin, Qingjie Zhang, Ctirad Uhe, and Xinfeng Tang. Eco-friendly high-performance silicide thermoelectric materials, National Science Review, 4(2017), 611-626.
10.Hongyao Xie, Xianli Su, Gang Zheng, Ting Zhu, Kang Yin, Yonggao Yan,Ctirad Uher, Mercouri G. Kanatzidis, and Xinfeng Tang, The Role of Zn in Chalcopyrite CuFeS2: Enhanced Thermoelectric Properties of Cu1–xZnxFeS2 with In Situ Nanoprecipitates, Advanced Energy Materials, 7.3(2017), **.
11.Gang Zheng, Xianli Su, XinranLi, Tao Liang, Hongyao Xie, Xiaoyu She, Yonggao Yan, Ctirad Uher, Mercouri G. Kanatzidis, Xinfeng Tang. Toward High-Thermoelectric-Performance Large-Size Nanostructured BiSbTe Alloys via Optimization of Sintering-Temperature Distribution, Advanced Energy Mater, 6(2016), **.
12.Dongwang Yang, Xianli Su, Yonggao Yan, Tiezheng Hu, Hongyao Xie, Jian He, Ctirad Uher, Mercouri G. Kanatzidis, Xinfeng Tang. Manipulating the Combustion Wave during Self-Propagating Synthesis for High Thermoelectric Performance of Layered Oxychalcogenide Bi_1-xPb_xCuSeO, Chemistry of Materials, 28(2016), 4628-4640.
13.Kang Yin, Xianli Su, Yonggao Yan, Yonghui You, Qiang Zhang, Ctirad Uher, Mercouri G. Kanatzidis, Xinfeng Tang. Optimization of the electronic band structure and the lattice thermal conductivity of solid solutions according to simple calculations: A canonical example of the Mg₂Si_1–x–yGe_xSn_yternary solid solution. Chemistry of Materials, (15)2016, 5538-5548.
14.Linchun Wu, Xianli Su, Yonggao Yan, Ctirad Uher, Xinfeng Tang, Ultra-Fast One-Step Fabrication of Cu2Se Thermoelectric Legs With Ni–Al Electrodes by Plasma-Activated Reactive Sintering Technique, Advanced Engineering Materials,30(2016), 57-62.
15.Xinfeng Tang, Xianli Su, Qingjie Zhang, Ctirad Uher. SHS-processed thermoelectric materials. In Materials aspect of thermoelectricity, Uher, C., Ed. CRC Press, Taylor & Francis Group: Boca Raton, Florida, U. S., 2016; 541-580.
16.Yun Zheng, Qiang Zhang, Xianli Su, Hongyao Xie, Shengcheng Shu, Tianle Chen, Gangjian Tan, Yonggao Yan, Xinfeng Tang, Ctirad Uher. Mechanically Robust BiSbTe Alloys with Superior Thermoelectric Performance: A Case Study of Stable Hierarchical Nanostructured Thermoelectric Materials, Advanced Energy Materials, 2015, 5 (5): **.
17.Shanyu Wang, Jiong Yang, Trevor Toll, Jihui Yang, Wenqing Zhang, Xinfeng Tang. Conductivity-limiting bipolar thermal conductivity in semiconductors, Scientific Reports, 2015, 5: 10136.
18.Gang Zheng, Xianli Su, Tao Liang, Qiangbing Lu, Yonggao Yan, Ctirad Uher, Xinfeng Tang. High thermoelectric performance of mechanically robust n-type Bi₂Te_3?xSe_xprepared by combustion synthesis, Journal of Materials Chemistry A, 2015, 3 (12): 6603-6613.
19.Xiaoyu She,Xianli Su, Huizhen Du, Tao Liang, Gang Zheng, Yonggao Yan, Rizwan Akram,Ctirad Uher, Xinfeng Tang.High thermoelectric performance of higher manganese silicides prepared by ultra-fast thermal explosion, Journal of Materials Chemistry C, 2015,3, 12116-12122.
20.Xianli Su, Fan Fu, Yonggao Yan, Gang Zheng, Tao Liang, Qiang Zhang, Xin Cheng, Dongwang Yang, Hang Chi, Xinfeng Tang, Qingjie Zhang and Ctirad Uher. Self-propagating high-temperature synthesis for compound thermoelectrics and new criterion for combustion processing, Nature Communications, 5(2014) , 4908,1-7.
21.Wei Liu, Xiaojian Tan, Kang Yin, Huijun Liu, Xinfeng Tang, Jin Shi, Qingjie Zhang and Ctirad Uher, Convergence of Conduction Bands as a means of Enhancing Thermoelectric Performance of n-type Mg₂Si_1-xSn_x Solid Solutions, Physical Review Letters, 108 (2012) ,166601.
22.Wenjie Xie, Jian He, Hye Jung Kang, Xinfeng Tang, Song Zhu, Mark Laver, Shanyu Wang, John R. D. Copley,Craig M. Brown, Qingjie Zhang, and Terry M. Tritt, Identifying the Specific Nanostructures Responsible for the High Thermoelectric Performance of (Bi,Sb)₂Te₃Nanocomposites, Nano Letters, 10(2010) , 3283–3289.







Chair Prof. Xinfeng Tang
Address:
State Key Laboratory of Advanced Technology for Materials Synthesis and Processing, Wuhan University of Technology
122 Luoshi Road, Wuchang Wuhan 430070, China
Email：tangxf@whut.edu.cnTel: 0086-**
EDUCATION
?Ph.D. Material Science, 10/2000, Tohoku University, Japan
?M.E.Engineering, 04/1988, Southwest Jiaotong University, China
?B.E. Engineering, 07/1983, Dalian Jiaotong University, China

WORK EXPERIENCE
?09/2011-present: Chair Professor, Wuhan University of Technology, China
?06/2001-05/2018:
Executive Vice Director, State Key Laboratory of Advanced Technology for Materials Synthesis and Processing, Wuhan University of Technology
Director, Advanced Materials Research Institute, Wuhan University of Technology
Professor, Wuhan University of Technology, China
?09/1997-03/2001: Research Assistant, Institute of Materials Research, Tohoku University, Japan
?06/1988-08/1997:
Associate Professor, State Key Laboratory of Advanced Technology for Materials Synthesis and Processing, Wuhan University of Technology
?08/1983-09/1985: Lecturer, Southwest Jiaotong University, China


RESEARCH PROJECT
Prof. Xinfeng Tang obtained his PhD at Tohoku University in 2000, and then came back to China and worked in Wuhan University of Technology as a full professor in April of 2001. Now he serves as chair Professor of Material Science,Vice President of Chinese Thermoelectric Society and APS Fellow, and he served as Board Member of International Thermoelectric Societyduring 2014~2017.
In Wuhan University of Technology, his research mainly focused on high performance thermoelectric materials, devices and application technologies. In recent years, his group has been funded by more than 10 projects from the Ministry of Science and Technology of China (973 program and 863 program), National Science Foundation of China (major international program, key program and general program), and the Ministry of Education of China. Supported by the above funding, his group has carried out a series of systematic and innovative research work in thermoelectrics: has discovered the conduction bands convergence effect in Mg₂Si_1-xSn_x; has pioneered and developed the MS-SPS, a new non-equillibrium and fast synthesis technique, for preparing multiple spatial-scale thermoelectric materials; has discovered the self-propagating combustion synthesis (SHS) phenomenon in thermoelectric materials, proposed anew thermodynamic criterion for the SHS process, and developed a new ultra-fast synthesis technique of SHS-SPS for thermoelectric materials. Moreover, his group and colleagues have developed a 100KW solar Thermoelectric-Photovoltaic hybrid power generation demonstration system and a KW scale waste heat recovery thermoelectric power generation system based on commercial vehicles.
He has published over 200 papers in peer-reviewed journals, such as Nature Communications, Science Advances, Physical Review Letters, Physical Review B, Nano Letters, Journal of American Chemical Society, Advanced Materials, Energy Environmental Science, Advanced Energy Materials, Chemistry of Materials, Journal of Materials Chemistry, Acta Materialia, Applied Physics Lettersand so on, and he was also the principal inventor on more than 50patents.
Representative Publications

1.Rigui Deng, Xianli Su, Shiqiang Hao, Zheng Zheng, Min Zhang, Hongyao Xie, Wei Liu, Yonggao Yan, Chris Wolverton, Ctirad Uher, Mercouri G. Kanatzidis and Xinfeng Tang. High thermoelectric performance in Bi_0.46Sb_1.54Te₃nanostructured with ZnTe.Energy & Environmental Science,11(2018), 1520-1535.
2.Zheng Zheng, Xianli Su, Rigui Deng, Constantinos Stoumpos, Hongyao Xie, Wei Liu, Yonggao Yan, Shiqiang Hao, Ctirad Uher, Chris Wolverton, Mercouri G. Kanatzidis and Xinfeng Tang. Rhombohedral to Cubic Conversion of GeTe via MnTe Alloying Leads to Ultralow Thermal Conductivity, Electronic Band Convergence, and High Thermoelectric Performance,Journal of the American Chemical Society,140.7(2018), 2673-2686.
3.Rigui Deng, Xianli Su, Zheng Zheng, Wei Liu, Yonggao Yan, Qingjie Zhang, Vinayak P Dravid, Ctirad Uher, Mercouri G Kanatzidis, Xinfeng Tang, Thermal conductivity in Bi0. 5Sb1. 5Te3+ x and the role of dense dislocation arrays at grain boundaries, Science Advances, 2018, 4(6), eaar5606.
4.Yonghui You, Xianli Su, Shiqiang Hao, Wei Liu, Yonggao Yan, Tingting Zhang, Min Zhang, Chris Wolverton, Mercouri G Kanatzidis, Xinfeng Tang, Ni and Se co-doping increases the power factor and thermoelectric performance of CoSbS, J. Mater. Chem. A, 2018, 6, 15123-15131.
5.Gang Zheng, Xianli Su, Hongyao Xie, Yuejiao Shu, Tao Liang, Xiaoyu She, Wei Liu, Yonggao Yan, Qingjie Zhang, Ctirad Uher, Mercouri G. Kanatzidis and Xinfeng Tang. High thermoelectric performance of p-BiSbTe compounds prepared by ultra-fast thermally induced reaction,Energy & Environmental Science,10(2017), 2638-2652.
6.Tao Liang, Xianli Su, Yonggao Yan, Gang Zheng, Xiaoyu She, Yonghui You, Ctirad Uher, Mercouri G. Kanatzidis and Xinfeng Tang. Panoscopic approach for high-performance Te-doped skutterudite, NPG Asia Materials, 9(2017), e352.
7.Xianli Su, Ping Wei, Han Li, Wei Liu, Yonggao Yan, Peng Li, Chuqi Su, Changjun Xie, Wenyu Zhao, Pengcheng Zhai, Qingjie Zhang, Xinfeng Tangand Ctirad Uher. Multi-Scale Microstructural Thermoelectric Materials:Transport Behavior, Non-Equilibrium Preparation, and Applications, Advanced Materials, 29.20(2017), **.
8.Hongyao Xie, Xianli Su, Yonggao Yan, Wei Liu, Liangjun Chen, Jiefei Fu, Jihui Yang, Ctirad Uher and Xinfeng Tang. Thermoelectric performance of CuFeS_2+2xcomposites prepared by rapid thermal explosion, NPG Asia Materials, 9(2017), e390.
9.Wei Liu, Kang Yin, Qingjie Zhang, Ctirad Uhe, and Xinfeng Tang. Eco-friendly high-performance silicide thermoelectric materials, National Science Review, 4(2017), 611-626.
10.Hongyao Xie, Xianli Su, Gang Zheng, Ting Zhu, Kang Yin, Yonggao Yan,Ctirad Uher, Mercouri G. Kanatzidis, and Xinfeng Tang, The Role of Zn in Chalcopyrite CuFeS2: Enhanced Thermoelectric Properties of Cu1–xZnxFeS2 with In Situ Nanoprecipitates, Advanced Energy Materials, 7.3(2017), **.
11.Gang Zheng, Xianli Su, XinranLi, Tao Liang, Hongyao Xie, Xiaoyu She, Yonggao Yan, Ctirad Uher, Mercouri G. Kanatzidis, Xinfeng Tang. Toward High-Thermoelectric-Performance Large-Size Nanostructured BiSbTe Alloys via Optimization of Sintering-Temperature Distribution, Advanced Energy Mater, 6(2016), **.
12.Dongwang Yang, Xianli Su, Yonggao Yan, Tiezheng Hu, Hongyao Xie, Jian He, Ctirad Uher, Mercouri G. Kanatzidis, Xinfeng Tang. Manipulating the Combustion Wave during Self-Propagating Synthesis for High Thermoelectric Performance of Layered Oxychalcogenide Bi_1-xPb_xCuSeO, Chemistry of Materials, 28(2016), 4628-4640.
13.Kang Yin, Xianli Su, Yonggao Yan, Yonghui You, Qiang Zhang, Ctirad Uher, Mercouri G. Kanatzidis, Xinfeng Tang. Optimization of the electronic band structure and the lattice thermal conductivity of solid solutions according to simple calculations: A canonical example of the Mg₂Si_1–x–yGe_xSn_yternary solid solution. Chemistry of Materials, (15)2016, 5538-5548.
14.Linchun Wu, Xianli Su, Yonggao Yan, Ctirad Uher, Xinfeng Tang, Ultra-Fast One-Step Fabrication of Cu2Se Thermoelectric Legs With Ni–Al Electrodes by Plasma-Activated Reactive Sintering Technique, Advanced Engineering Materials,30(2016), 57-62.
15.Xinfeng Tang, Xianli Su, Qingjie Zhang, Ctirad Uher. SHS-processed thermoelectric materials. In Materials aspect of thermoelectricity, Uher, C., Ed. CRC Press, Taylor & Francis Group: Boca Raton, Florida, U. S., 2016; 541-580.
16.Yun Zheng, Qiang Zhang, Xianli Su, Hongyao Xie, Shengcheng Shu, Tianle Chen, Gangjian Tan, Yonggao Yan, Xinfeng Tang, Ctirad Uher. Mechanically Robust BiSbTe Alloys with Superior Thermoelectric Performance: A Case Study of Stable Hierarchical Nanostructured Thermoelectric Materials, Advanced Energy Materials, 2015, 5 (5): **.
17.Shanyu Wang, Jiong Yang, Trevor Toll, Jihui Yang, Wenqing Zhang, Xinfeng Tang. Conductivity-limiting bipolar thermal conductivity in semiconductors, Scientific Reports, 2015, 5: 10136.
18.Gang Zheng, Xianli Su, Tao Liang, Qiangbing Lu, Yonggao Yan, Ctirad Uher, Xinfeng Tang. High thermoelectric performance of mechanically robust n-type Bi₂Te_3?xSe_xprepared by combustion synthesis, Journal of Materials Chemistry A, 2015, 3 (12): 6603-6613.
19.Xiaoyu She,Xianli Su, Huizhen Du, Tao Liang, Gang Zheng, Yonggao Yan, Rizwan Akram,Ctirad Uher, Xinfeng Tang.High thermoelectric performance of higher manganese silicides prepared by ultra-fast thermal explosion, Journal of Materials Chemistry C, 2015,3, 12116-12122.
20.Xianli Su, Fan Fu, Yonggao Yan, Gang Zheng, Tao Liang, Qiang Zhang, Xin Cheng, Dongwang Yang, Hang Chi, Xinfeng Tang, Qingjie Zhang and Ctirad Uher. Self-propagating high-temperature synthesis for compound thermoelectrics and new criterion for combustion processing, Nature Communications, 5(2014) , 4908,1-7.
21.Wei Liu, Xiaojian Tan, Kang Yin, Huijun Liu, Xinfeng Tang, Jin Shi, Qingjie Zhang and Ctirad Uher, Convergence of Conduction Bands as a means of Enhancing Thermoelectric Performance of n-type Mg₂Si_1-xSn_x Solid Solutions, Physical Review Letters, 108 (2012) ,166601.
22.Wenjie Xie, Jian He, Hye Jung Kang, Xinfeng Tang, Song Zhu, Mark Laver, Shanyu Wang, John R. D. Copley,Craig M. Brown, Qingjie Zhang, and Terry M. Tritt, Identifying the Specific Nanostructures Responsible for the High Thermoelectric Performance of (Bi,Sb)₂Te₃Nanocomposites, Nano Letters, 10(2010) , 3283–3289.
PATENT

INTERNATIONAL CONFERENCE
Invited talks:
2018, 11th Asian-Australasian Conference on Composite Materials (ACCM-11), Titled“Facile Room Temperature Solventless Synthesis of High Thermoelectric Performance Ag₂Q (Q = S, Se, Te) via Dissociative Adsorption Reaction”
2015, APS March Meeting, Titled“Self-propagating high temperature synthesis for compound thermoelectrics: a new criterion for applicability of combustion processing”
2014, 33th International Conference on Thermoelectrics (ICT 2014), Titled“Self-propagating high temperature synthesis for compound thermoelectrics: a new criterion for applicability of combustion processing”
2014, APS March Meeting, Titled“Thermal stability and strategy for improving performance of Mg₂Si_1-xSn_xthermoelectric materials”


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