教师

平炜炜

    

【平炜炜】


   联系方式:wwping@hfut.edu.cn

         



       副教授(黄山学术骨干),硕士生导师。202012月毕业于西安交通大学电气工程专业,获博士学位。曾于美国马里兰大学从事博士后研究。主要从事固态锂金属电池和超快速高温合成(UHS)在储能陶瓷,金属,玻璃等领域的研究及应用。近5年来,已在Science, Science Advance, Advanced Materials, Advanced Energy Materials等高水平期刊发表文章近20篇。



教育及工作经历

  l  教育简历

2017/09 - 2019/10,美国马里兰大学,材料科学与工程,联合培养博士

2015/03 - 2020/12,西安交通大学,电气工程,博士

  l  工作简历

2019/10 - 2021/08,美国马里兰大学,材料科学与工程,博士后

2021/09 - 至今, 合肥工业大学,材料科学与工程学院

研究方向:

锂离子电池,固态锂金属电池,超快速高温合成(UHS)在储固态锂离子电池领域的研究及应用。

主讲课程:

      超级电容器材料与技术

 科研项目:

         1. 超快速高温制备氧化物/硫化物双层固态电解质薄膜及锂离子输运特性研究国家自然科学基金青年基金,主持,2023.1-2025.12

         2. 高性能三维导通复合固态电解质薄膜的超快高温研发和锂传输机理研究,安徽省自然科学基金青年基金,主持,2022.1-2023.12

  代表性论文/专利/著作:

[1]   Chengwei Wang*; Weiwei Ping*; Q. Bai*; H. Cui*; R. Hensleigh*; R. Wang,; A.H. Brozena; Z. Xu; J. Dai; Y. Pei; C. Zheng; G. Pastel; J. Gao; X. Wang; H. Wang; J. Zhao; B. Yang; X. Zheng; J. Luo; X. Zheng; Y. Mo; B. Dunn; L. Hu, “A General Method to Synthesize and Sinter Bulk Ceramics in Seconds,” Science (Cover Article), 368, 6490, 521-526, 2020. 

[2]   Weiwei Ping*; Chengwei Wang*; Ruiliu Wang*; Qi Dong; Zhiwei Lin; A.H. Brozena; Jiaqi Dai; Jian Luo; Liangbing Hu, “Printable, High-Performance Solid-State Electrolyte Films,” Science Advances, 6, eabc8641, 2020.

[3]   Weiwei Ping*; Chengwei Wang*; Zhiwei Lin; Emily Hitz; Chunpeng Yang; Howard Wang; Liangbing Hu, “Reversible Short-Circuit Behaviors in Garnet-Based Solid-State Batteries,” Advanced Energy Materials, 10, 25, 2020.

[4]   Ruiliu. Wang*; Weiwei Ping*; Chengwei Wang*; Yunsheng Liu; Jinlong Gao; Qi Dong; Xizheng Wang; Yifei Mo; Liangbing Hu, “Computation-Guided Synthesis of New Garnet-Type Solid-state Electrolytes via an Ultrafast Sintering Technique,” Advanced Materials, 2005059, 2020.

[5]   Weiwei Ping*; Chunpeng Yang*; Yinhua Bao*; Chengwei Wang; Hua Xie; Emily Hitz; Jian Cheng; Teng Li; Liangbing Hu, A silicon anode for garnet-based all-solid-state batteries: Interfaces and nanomechanicsEnergy Storage Materials, 21, 246-252, 2019.

[6] Weiwei Ping; Wenfeng Liu; Shengtao Li, Enhanced energy storage property in glass-added Ba(Zr0.2Ti0.8)O3-0.15(Ba0.7Ca0.3)TiO3 ceramics and the charge relaxation. Ceramics International, 45, 9, 11388-11394, 2019.

[7]   Weiwei Ping; Lu Jin; Yong Wu; Xiaoyan Xue; Xiang Zhao, On the mechanism of Pd(0)-catalyzed coupling of propargylic carbonates with N-tosylhydrazones: density functional theory survey, Tetrahedron, 70, 49, 9373-9380, 2014.

[8]   Wenfeng Liu; Weiwei Ping; Shengtao Li, Enhanced Energy Storage using Ba(Zr0.2Ti0.8)O3-0.15(Ba0.7Ca0.3)TiO3 Ceramics with BaO-SrO-TiO2-Al2O3-SiO2-BaF2 Glass Addition, Energy Technology, 5, 8, 1423-1428, 2017.

[9]   Chengwei Wang*; Wei Zhong*; Weiwei Ping; Zhiwei Lin; Ruiliu Wang; Jiaqi Dai; Miao Guo; Wei Xiong; Ji-Cheng Zhao; Liangbing Hu, “Rapid Synthesis and Sintering of Metals from Powders,” Advanced Science, 2020.

[10] Chengwei Wang*; Hua Xie*; Weiwei Ping; J. Dai; G. Feng; Y. Yao; S. He; J. Weaver; H. Wang; K. Gaskell; Liangbing Hu, “A General, Highly Efficient, High Temperature Thermal Pulse Toward High Performance Solid State Electrolyte,” Energy Storage Materials, 17, 234-241, 2018.

[11] Chunpeng, Yang*; Hua Xie*; Weiwei Ping; Kun Fu; Boyang Liu; Jiancun Rao; Jiaqi Dai; Chengwei Wang; Glenn Pastel; Liangbing Hu, An Electron/Ion Dual-Conductive Alloy Framework for High-Rate and High-Capacity Solid-State Lithium-Metal Batteries, Advanced Materials, 31, 3, 1804815, 2019.

[12] Zhiwei Lin*; Chengwei Wang*; Qi Dong; Weiwei Ping; Ji Qian; Alexandra Brozena; Xizheng Wang; Ruiliu Wang; Shuaiming He; Xinpeng Zhao; Yong Pei; Chaolun Zheng; Guangran Zhang; Bao Yang; Yiquan Wu; Jian Luo; Liangbing Hu, “Speedy, Pressureless Sintering Toward Transparent Glass Discovery,” Science Advances, 2020.

[13] Geng, Zhong*; Chengwei Wang*; Ruiliu Wang; Weiwei Ping; Shaomao Xu; Haiyu Qiao; Mingjin Cui; Xizheng Wang; Yubing Zhou; Dylan Jacob Kline; Michael R Zachariah; Liangbing Hu, Rapid, high-temperature microwave soldering toward a high-performance cathode/electrolyte interface, Energy Storage Materials, 30, 385-391, 2020.

[14] Chengwei Wang*; S. Wang*; G. Chen; W. Kong; Weiwei Ping; J. Dai; G. Pastel; H. Xie; S. He; S. Das; L. Hu, “Flexible, Bio-Compatible Nanofluidic Ion Conductor,” Chemistry of Materials, 30, 21, 7707-7713, 2018.

[15] Wentao, Gan*; Chaoji Chen*; Hyun-Tae Kim; Zhiwei Lin; Jiaqi Dai; Zhihua Dong; Zhan Zhou; Weiwei Ping; Shuaiming He; Shaoliang Xiao; Miao Yu; Liangbing Hu, Single-digit-micrometer thickness wood speaker, Nature communications, 10, 1, 1-8, 2019.

[16] Wentao, Gan*; Chaoji Chen*; Michael Giroux; Geng Zhong; Mukund Goyal; Yilin Wang; Weiwei Ping; Jianwei Song; Shaomao Xu; Shuaiming He; Miaolun Jiao; Chao Wang; Liangbing Hu, Conductive Wood for High-Performance Structural Electromagnetic Interference Shielding, Chemistry of Materials, 32, 12, 5280-5289, 2020.

[17] Wentao, Gan*; Chaoji Chen*; Zhengyang Wang; Yong Pei; Weiwei Ping, Shaoliang Xiao; Jiaqi Dai; Yonggang Yao; Shuaiming He; Beihan Zhao; Siddhartha Das; Bao Yang; Peter B Sunderland; Liangbing Hu, Fire-Resistant Structural Material Enabled by an Anisotropic Thermally Conductive Hexagonal Boron Nitride Coating, Advanced Functional Materials, 30, 10, 1909196, 2020.

[18] Yun, Qiao*; Yang Liu*; Chaoji Chen*; Hua Xie; Yonggang Yao; Shuaiming He; Weiwei Ping; Boyang Liu; Liangbing Hu, 3D-Printed Graphene Oxide Framework with Thermal Shock Synthesized Nanoparticles for Li-CO2 Batteries, Advanced Functional Materials, 28, 51, 1805899, 2018.