当前位置: X-MOL首页全球导师 国内导师 › 王锐

个人简介

教育背景及工作经历: 2003 年09月-2007年06月:重庆大学  应用物理专业   本科 2007 年09月-2009年06月:重庆大学  凝聚态物理专业  硕士 2009 年03月-2012年06月:重庆大学  凝聚态物理专业  博士 2012 年07月-2014年08月:重庆大学  物理学院物理系  讲师 2013年07月-2013年08月:中科院理论物理研究所访问学者 2014年9月 晋升为副教授 2016年02月-2016年09月:南方科技大学高级访问学者 2017年08月-2018年08月: 南方科技大学Visiting Associate Professor 2018年 入选重庆大学后备拔尖人才 (B类) 2019年 入选重庆英才·青年拔尖人才 科研情况: 从事缺陷物理、计算凝聚态物理、纳米系统的电子与输运性质、拓扑材料的性质研究和设计、纳米表面的催化机理等研究。到目前为止,已经在国际主流物理、材料SCI期刊,如Phys. Rev. Lett., Nano Letters, Phys. Rev. B, Phys. Rev. Mater., J. Phys. Chem. Lett., Nanoscale, Acta Materia., Philos. Mag.等发表文章80余篇,第一作者和通讯作者论文40余篇,引用达700余次。曾获得2010年教育部博士“学术新人奖“、黄尚廉院士青年创新奖、重庆大学学术奖、宝钢教学基金奖等。主持完成国家自然科学基金项目1项、中央高校基金重点项目1项、中央高校基金面上项目2项、参与国家自然基金重大研究计划项目1项和科技部973重大专项子课题1项。担任了国际期刊Phys. Rev. B, Nanoscale, Nano Research, RSC Advances, PCCP, Philos. Mag. 等杂志(SCI收录)审稿人, 国家自然科学基金通讯评审专家,教育部学位中心通讯评审专家,SCI期刊Advances in Materials Science and Engineering 编辑(Editor)。 人才培养: 1、担任本科生专业课《热学》、公共基础课《大学物理》、以及物理学院研究生《固体能带理论》、《凝聚态物理》等课程教学; 2、长期担任全国大学生物理学术竞赛教练,第4、5、6、7届全国大学物理物理学术竞赛裁判; 3、培养研究生获得研究生国家奖学金、获国际Maxwell Prize 提名等。 在研项目: 重庆英才青年拔尖人才计划项目( 2020.01-2022.12,40万),负责人 国家自然基金面上项目(批准号:11974062, 2020.01-2023.12,62万),负责人 重庆市基金面上项目(批准号:cstc2019jcyj-msxmX0563,2019.07-2022.06,10万),负责人 重庆大学后备拔尖人才项目 (批准号:cqu2018CDHB1B01,2018.07-2021.07,40万), 负责人 中央高校基金提升项目(批准号:2019CDXYWL0029,2019. 01-2020. 12),负责人 国家自然基金重大研究计划项目 (批准号:91634106,2017.01—2020.12,),参与 国家自然科学基金青年项目(批准号:11304403,2014.01—2016.12),负责人 ; 中央高校基金面上项目(批准号:106112015CDJXY300006, 2015.01—2016.12),负责人; 重庆大学人才启动基金,负责人 ; 中央高校基金重点项目(批准号:CQDXWL-2013-Z011,2013.09—2015.08),负责人 ; 国家自然科学基金面上项目(批准号:11074313),主研; 国家自然科学基金青年项目(批准号:11104361),主研; 科技部国家基础研究规划项目(973计划)子课题(批准号:2011CB209401-4),主研。 已获奖励: 重庆英才青年拔尖人才(2019年) 重庆大学后备拔尖人才 (B 类) 教育部博士研究生“学术新人奖”; 第一届国际量子输运讲习班“研究生奖学金”(中国人民大学,北京); 宝钢教育基金优秀学生奖 ; 重庆大学2009年度“十佳班主任”; 重庆市优秀毕业研究生; 黄尚廉院士创新个人奖; 重庆大学“学术奖”; “高教社杯”全国大学生数学建模竞赛重庆赛区二等奖。

研究领域

研究方向: 计算凝聚态物理; 拓扑材料的性质研究和设计; 纳米系统的缺陷电子学和输运性质; 缺陷物理和位错的热力学机制; 固体热力学性质; 纳米表面的催化机理。

近期论文

查看导师新发文章 (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)

代表学术论文: * Corresponding Author # Equal Contributions ▲Chao Zhang*, Xian-Yong Ding, Li-Yong Gan, Yu Cao, Bing-Sheng Li, Xiaozhi Wu, Rui Wang*. Symmetry-guaranteed ideal Weyl semimetallic phase in face-centered orthogonal C6.Phys. Rev. B 101, 235119(2020).(*Corresponding Author) ▲Duan Lei, Wang Xiancheng*, Zhan Fangyang, Zhang Jun, Hu Zhiwei, Zhao Jianfa, Li Wenmin, Deng Zheng, Yu Runze, Lin Hong-Ji, Chen Chien-Te, Wang Rui*, Jin Chang-Qing*,Science China Materials, doi: https://doi.org/10.1007/s40843-020-1344-x (2020). ( *Corresponding Author). ▲Rui Wang*, Yuanjun Jin, Bowen Xia, and Hu Xu*, Topological Quantum States in Magnetic Oxides, J. Phys. Chem. Lett. 11, 4036−4042 (2020) (Perspective). ( *Corresponding Author) ▲Ruiling Zou, Fangyang Zhan, Baobing Zheng, Xiaozhi Wu, Jing Fan, Rui Wang*. Intrinsic quantum anomalous Hall phase induced by proximity in germanene/Cr2Ge2Te6 van der Waals heterostructure. Phys. Rev. B 101, 161108 (2020) (Rapid Comm.) arXiv:2002.12624 (2020).(*Corresponding Author) ▲Baobing Zheng, Bowen Xia, Rui Wang, Zhongjia Chen, Jinzhu Zhao, Yujun Zhao, and Hu Xu. Ideal type-III nodal-ring phonons. Phys. Rev. B 101, 100303(Rapid Comm.) (2020). ▲Jiali Yang, Baobing Zheng, Zhongjia Chen, Wangping Xu, Rui Wang*, Xu Hu*. Robust Topological States in Bi2Se3 against Surface Oxidation. J. Phys. Chem. C124, 6253-6259 ( 2020).(*Corresponding Author) ▲R. Wang, B. W. Xia, Z. J. Chen, B. B. Zheng, Y. J. Zhao, and H. Xu. Symmetry-protected topological triangular Weyl complex. Phys. Rev. Lett. 124, 105303 (2020). ▲B. W. Xia, R. Wang#(#Equal Contributions), Z. J. Chen, Y. J. Zhao, and H. Xu. Symmetry-Protected Ideal Type-II Weyl Phonons in CdTe. Phys. Rev. Lett. 123, 065501 (2019). ▲ B. B. Zheng, B. W. Xia, R. Wang#(#Equal Contributions), J. Z. Zhao, Z. J. Chen, Y. J. Zhao, and H. Xu. Tunable ferromagnetic Weyl fermions from a hybrid nodal ring. npj Computational Materials 5, 74 (2019). ▲F. Y. Zhan, W. P. Xu, R. L. Zou, J. L. Yang, J. Fan, X. Z. Wu, and R. Wang*. Interplay of Charged States and Oxygen Dissociation Induced by Vacancies in Phosphorene. J. Phys. Chem. C123, 44, 27080-27087 (2019) ▲B. W. Xia, Y. J. Jin, J. Z. Zhao, Z. J. Chen, B. B. Zheng, Y. J. Zhao, R. Wang*, and H. Xu*. Robust Twin Pairs of Weyl Fermions in Ferromagnetic Oxides. Phys. Rev. Lett. 122, 057205 (2019). (*Corresponding Author) ▲Y. J. Jin, Z. J. Chen, B. W. Xia, Y. J. Zhao, R. Wang*, and H. Xu*. Large-gap quantum anomalous Hall phase in hexagonal organometallic frameworks. Phys. Rev. B 98, 245127 (2018) (*Corresponding Author) ▲Y. J. Jin, Z. J. Chen, B. W. Xia, Y. J. Zhao, R. Wang*, and H. Xu*. Ideal intersecting nodal-ring phonons in bcc C8. Phys. Rev. B 98, 220103 (2018) (Rapid Comm.) (*Corresponding Author) ▲Y. J. Jin, R. Wang*, and H. Xu*. Recipe for Dirac Phonon States with a Quantized Valley Berry Phase in Two-Dimensional Hexagonal Lattices. Nano Lett. 18, 7755-7760 (2018). (*Corresponding Author) ▲Y. J. Jin, R. Wang# (#Equal Contributions), B. W. Xia, B. B. Zheng, and H. Xu. Three-dimensional quantum anomalous Hall effect in ferromagnetic insulators. Phys. Rev. B, 98, 081101 (2018) (Rapid Comm.) ▲ J. Y. Jin, L. Y. Gan, R. Wang# (#Equal Contributions), Z. J. Zhao, Y. Y. Shan, J. F. Liu, H. Xu.Topological Rashba-like edge states in large-gap quantum spin Hall insulators. Phys. Rev. Mater. 2, 114207 (2018). ▲ Jiali Yang, Yuanjun Jin, Wangping Xu, Baobing Zheng*, Rui Wang*, Xu Hu*. Oxidation-Induced Topological Phase Transition in Monolayer 1T’-WTe2. J. Phys. Chem. Lett. 9, 4783−4788 (2018). (*Corresponding Author) ▲R. Wang, J. Z. Zhao, Y. J. Jin, Y. P. Du, Y. X. Zhao, H. Xu, and S. Y. Tong, Nodal line fermions in magnetic oxides, Phys. Rev. B 97, 241111(Rapid Comm.) (2018). ▲R. Wang, Y. J. Jin, J. Z. Zhao, Z. J. Chen, Y. J. Zhao, and H. Xu. Ferromagnetic Weyl fermions in CrO2. Phys. Rev. B 97, 195157 (2018). ▲R. Wang, J. Z. Zhao, Y. J. Jin, W. P. Xu, L. -Y. Gan, X. Z. Wu, H. Xu, S. Y. Tong. Recipe for Generating Weyl Semimetals with Extended Topologically Protected Features. Phys. Rev. B 96, 121104 (Rapid Comm.) (2017). ▲Y. Jin, R. Wang# (#Equal Contributions), Z. J. Chen, J. Z. Zhao, Y. J. Zhao, and H. Xu, FerromagneticWeyl semimetal phase in a tetragonal structure. Phys. Rev. B 96, 201102 (Rapid Comm.) (2017). ▲Y. Jin, R. Wang# (#Equal Contributions), J. Zhao, C. Zheng, L. Y. Gan, J. Liu, H. Xu, S. Y. Tong, The Prediction of a Family Group of Two-dimensional Node-Line Semimetals. Nanoscale 9, 13112 (2017) . ▲L.-Y. Gan, R. Wang, Y. J. Jin, D. B. Ling, J. Z. Zhao, W. P. Xu, J. F. Liu, H. Xu, Pressure-induced Topological Node-Line Semimetals in Alkaline-Earth Hexaborides XB6 (X=Ca, Sr, Ba) Phys. Chem. Chem.Phys. 19, 8210 (2017). ▲Wang Rui*, Jiali Yang, Xiaozhi Wu, and Shaofeng Wang. Local charge states in hexagonal boron nitride with Stone-Wales defects. Nanoscale, 8, 8210-8219 (2016). (*Corresponding Author) ▲Yingzhao Jiang, Rui Wang*, Shaofeng Wang, Temperature-dependent dislocation properties of aluminum from the improved Peierls-Nabarro model and first-principles. Philos. Mag., 96, 2829-2852 (2016). (*Corresponding Author) ▲Xie Ting, Wang Rui*, Shaofeng Wang, and Wu Xiaozhi*. Charge transfer of edge states in zigzag silicene nanoribbons with Stone-Wales defects from first-principles. Appl. Surf. Sci. 383, 310-316 (2016). (*Corresponding Author) ▲Wang Rui*, Wang Shaofeng, Wu Xiaozhi, Pressure induced structural instability of FeV intermetallic compound with B2 ordering, J. Alloy. Comp., 650:537-541 (2015). (*Corresponding Author) ▲Wang Shaofeng, Wang Rui, The core structure and pseudo-magnetic field of the dislocation in graphene, EPL, 104(2): 26002 (2013). ▲Wang Shaofeng, Huang Lili, and Wang Rui. The 90° partial dislocation in semiconductor silicon: An investigation from the lattice P-N theory and the first principle calculation. Acta Mater., 187-201 (2016). ▲Wang Rui*, Wang Shaofeng, Wu Xiaozhi, The formation and electronic properties of hydrogenated bilayer silicene from first-principles, J. Appl. Phys., 116(2):024303 (2014). (*Corresponding Author) ▲Wang Rui*, Wang Shaofeng, Wu Xiaozhi, First-principles phonon calculations on the lattice dynamics and thermodynamics of rare-earth intermetallics TbCu and TbZn, Intermetallics, 43: 65-70 (2013). (*Corresponding Author) ▲Wang Rui*, Wang Shaofeng, Wu Xiaozhi, The third-order elastic moduli and pressure derivatives for AlRE (RE = Y, Pr, Nd, Tb, Dy, Ce) intermetallics with B2-structure: A first-principles study , Solid State Comm.,151(4-15): 996-1000 (2011). (*Corresponding Author) ▲Wang Rui*, Wang Shaofeng, Wu Xiaozhi. First-principles determination of dislocation properties in Magnesium based on the improved Peierls-Nabarro equation. Phys. Scr., 81 (6):065601 (2010). (*Corresponding Author) (Cover Page) ▲Wu Xiaozhi, Wang Rui*, Wang Shaofeng et al. Ab initio calculations of generalized stacking fault energy surfaces and surface energies for FCC metals. Appl. Surf. Sci., 256(21):6345-6349 (2010). (*Corresponding Author)

推荐链接
down
wechat
bug