彭栋梁 - 厦门大学

个人简介

彭栋梁教授，理学和工学双博士，博士生导师，现任厦门大学材料学院院长。国家杰出青年科学基金获得者，国家重点研发计划“纳米科技专项”项目负责人，福建省“科技创新领军人才”，2015-2017年度福建省优秀教师。中国材料研究学会理事会理事，中国电子学会应用磁学分会委员会委员，中国物理学会磁学专业委员会委员，中国金属学会材料科学分会委员会委员，中国金属学会功能材料分会委员会理事，中国材料研究学会纳米材料与器件分会理事会理事，Steering Committee Member of the International Conference on Fine Particle Magnetism (2012.6--至今)，《Journal of Materials Science: Materials in Electronics》、《Scientific Reports》、《金属功能材料》和《功能材料》等杂志编委会委员。工作经历 1983年7月-1995年9月兰州大学物理系助教、讲师、副教授 1998年1月-2001年11月日本东北大学-日本文部科学省科学技术振兴事业团研究员 2001年12月-2003年11月日本名古屋工业大学-日本文部科学省日本学术振兴会(JSPS) 特别研究员 2003年12月-2005年3月日本名古屋工业大学材料科学与工程系高级研究员 2005年4月-2006年3月日本名古屋工业大学材料科学与工程系副教授 2005年12月-至今厦门大学材料科学与工程系教授、博士生导师教育经历 1983年6月兰州大学物理系本科毕业，获理学学士学位 1989年6月兰州大学物理系固体物理专业硕士研究生毕业，获理学硕士学位 1993年9月兰州大学物理系凝聚态物理专业，博士研究生入学 1995年10月-1997年10月作为中国和日本联合培养博士生在日本东北大学金属材料研究所留学 1997年12月兰州大学物理系凝聚态物理专业博士研究生毕业，获理学博士学位 2002年3月再获日本名古屋工业大学材料科学与工程专业，获工学博士学位

研究领域

磁性材料与自旋电子学物理、能源材料、纳米和低维功能材料

近期论文

查看导师最新文章（温馨提示：请注意重名现象，建议点开原文通过作者单位确认）

P. Liu, H. Zhang, W. He, T. Xiong, Y. Cheng, Q. S. Xie*, Y. Ma, H. Zheng, L. S. Wang, Z. Z. Zhu, Y. Peng, L. Mai*, and D. L. Peng*, “Lithium Deficiencies Engineering in Li-Rich Layered Oxide Li1.098Mn0.533Ni0.113Co0.138O2 for High Stability Cathode”, J. Am. Chem. Soc., 141 (2019) 10876-10882. W. He, P. Liu, B. Qu*, Z. Zheng, P. Deng, P. Li, S. Li, H. Huang, L. Wang, Q. Xie, and D. L. Peng*, “Uniform Na+ Doping-Induced Defects in Li- and Mn-rich Cathodes for High-Performance Lithium-ion Batteries”, Adv. Science, (2019) 1802114, DOI: 10.1002/advs.201802114. Y. Ma, P. Liu, Q. Xie*, G. Zhang, H. Zheng, Y. Cai, Z. Li, L. Wang, Z.-Z. Zhu, L. Mai*, and D. L. Peng*, “Double-shell Li-rich layered oxide hollow microspheres with sandwich-like carbon@spinel@layered@spinel@carbon shells as high-rate lithium ion battery cathode”, Nano Energy, 59 (2019) 184-196. Z. Qiao, F. Zhou, Q. Zhang, F. Pei, H. Zheng, W. Xu, P. Liu, Y. Ma, Q. S. Xie*, L. S. Wang, X. L. Fang, and D. L. Peng*, “Chemisorption and electrocatalytic effect from CoxSny alloy for high performance lithium sulfur batteries”, Energy Storage Materials, 23 (2019) 62-71. P. Liu, W. He, Q. S. Xie*, Y. Cheng, W. Xu, Z. Qiao, L. S. Wang, B. Qu, Z. Z. Zhu, and D. L. Peng*, “A Guideline for Tailoring Lattice Oxygen Activity in Lithium-Rich Layered Cathodes by Strain”, J. Phys. Chem. Lett., 10 (2019) 2202. J. Lin, J. M. Lim, D. H. Youn, Y. Lin, Y. Cai, K. Kawashima, J. H. Kim, D. L. Peng*, H. Guo*, G. Henkelman, A. Heller, and C. B. Mullins*, “Cu4SnS4-Rich Nanomaterials for Thin-Film Lithium Batteries with Enhanced Conversion Reaction”, ACS Nano, 13 (2019) 10671-10681. Y. Cai, L. Ku, L.S. Wang*, Y. Ma, H. Zheng, W. Xu, J. Han, B. Qu, Y. Chen, Qingshui Xie*, and D. L. Peng*, “Engineering oxygen vacancies in hierarchically Li-rich layered oxide porous microspheres for high-rate lithium ion battery cathode”, Sci. China Mater., 62 (2019) 1374-1384. Q. Chen, Y. Yang, H. Zheng, Q. S. Xie*, X. Yan, Y. Ma, L. S. Wang, and D. L. Peng*, “Electrochemically induced highly ion conductive porous scaffolds to stabilize lithium deposition for lithium metal anodes”, J. Mater. Chem. A, 7 (2019) 11683. B. Deng, Y. Chen*, P. Wu, J. Han, Y. Li, H. Zheng, Q. S. Xie, L. S. Wang, and D. L. Peng*, “Lithium-rich layered oxide nanowires bearing porous structures and spinel domains as cathode materials for lithium-ion batteries”, Journal of Power Sources, 418 (2019) 122-129. Q. S. Xie, P. Liu, D. Zeng, W. Xu, L. S. Wang, Z. Z. Zhu, L. Mai, and D. L. Peng*, “Dual Electrostatic Assembly of Graphene Encapsulated Nanosheet-Assembled ZnO-Mn-C Hollow Microspheres as a Lithium Ion Battery Anode”, Adv. Funct. Mater., 28 (2018) 1707433. D Zeng, P. Wu, W. J. Ong*, B. Tang, M. Wu, H. Zheng, Y. Chen*, and D. L. Peng*, “Construction of network-like and flower-like 2H-MoSe2 nanostructures coupled with porous g-C3N4 for noble-metal-free photocatalytic H2 evolution under visible light”, Applied Catalysis B: Environmental, 233 (2018) 26-34. D Zeng, W. Xu, W. J. Ong*, J. Xu, H. Ren, Y. Chen*, and D. L. Peng*, “Toward noble-metal-free visible-light-driven photocatalytic hydrogen evolution: Monodisperse sub–15 nm Ni2P nanoparticles anchored on porous g-C3N4 nanosheets to engineer 0D-2D heterojunction interfaces”, Applied Catalysis B: Environmental, 221 (2018) 47-55. Z. Zheng, H. Wu, H. Chen, Y. Cheng, Q. B. Zhang*, Q. S. Xie, L. S. Wang, K. Zhang, M. S. Wang, and D. L. Peng*, “Fabrication and understanding of Cu3Si-Si@carbon@graphene nanocomposites as high-performance anodes for lithium-ion batteries”, Nanoscale, 10 (2018) 22203-22214. X. Liu, L. S. Wang*, Y. Ma, Y. Qiu, Q. S. Xie, Y. Chen, and D. L. Peng*, “Facile synthesis and microwave absorption properties of yolk-shell ZnO-Ni-C/RGO composite materials”, Chemical Engineering Journal, 333 (2018) 92-100. Q. F. Zhang, H. Zheng, L. S. Wang, A. Su, X. Liu, J. Xie, Y. Z. Chen, and D. L. Peng*, “Influence of surface and interface modification on the electrical transport behaviors in Co@Cu nanocomposite films”, J. Magn. Magn. Mater., 460 (2018) 34-40. L. Lin, Y. Ma, Q. S. Xie*, L. S. Wang, Q. Zhang, and D. L. Peng*, “Copper-Nanoparticle-Induced Porous Si/Cu Composite Films as an Anode for Lithium Ion Batteries”, ACS Nano, 11 (2017) 6893-6903. Q. S. Xie, Y. Ma, X. Wang, D. Zeng, L. S. Wang, L. Mai, and D. L. Peng*, “Electrostatic Assembly of Sandwich-like Ag-C@ZnO-C@Ag-C Hybrid Hollow Microspheres with Excellent High-Rate Lithium Storage Properties”, ACS Nano, 10 (2016) 1283-1291. J. Huang, Y. Ma, Q. S. Xie,* H. Zheng, J. Yang, L. S. Wang, and D. L. Peng*, “3D Graphene Encapsulated Hollow CoSnO3 Nanoboxes as a High Initial Coulombic Efficiency and Lithium Storage Capacity Anode”, Small, 14 (2017) 1703513. X. Liu, L. S. Wang*, Y. Ma, H. Zheng, L. Lin, Q. Zhang, Y. Chen, Y. Qiu, and “Enhanced Microwave Absorption Properties by Tuning Cation Deficiency of Perovskite Oxides of Two-Dimensional LaFeO3/C Composite in X-Band”, ACS Appl. Mater. Interfaces, 9 (2017) 7601. Qingshui Xie, Liang Lin, Yating Ma, Deqian Zeng, Jingren Yang, Jian Huang, Laisen Wang*, and Dong-Liang Peng*, “Synthesis of ZnO-Cu-C yolk-shell hybrid microspheres with enhanced electrochemical properties for lithium ion battery anodes”, Electrochimica Acta, 226(2017)79-88.