高峻峰
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  • 教师姓名:高峻峰
  • 性别:
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  • 在职信息:在职
  • 职称:教授
  • 所在单位:物理学院
  • 学位:博士
  • 学科:凝聚态物理
  • 毕业院校:大连理工大学
  • 办公地点:物理学院323
  • 个人简介
  • 研究方向
  • 社会兼职
  • 教育经历
  • 工作经历
  • 团队成员
  • 其他联系方式

主要从事低维材料生长机理的前沿研究,从团簇科学出发,结合第一性原理计算和经典生长模型,研究了在石墨烯、硅烯和磷烯等二维材料的成核机理。通过理论模拟假设,提出了可稳定性磷烯团簇的衬底选择判据,被科技媒体PHYS.ORG等报导;首次提出单层磷烯锯齿边会卷曲成管状重构,解决了实验和理论对磷烯边界电子性质的冲突,并预测了磷烯管状边独特的热学特性;申请人理论设计了空气中稳定磷烯的方案,该方案显著提高磷烯寿命;申请人重新解释了3D Dirac 费米子材料Cd3As2的表面与表面重构,深入了认识了该重构对其电子性质的影响,并首次研究了该材料氧化的机理和保护机理。并在二维材料边结构、衬底选择和稳定性和其它低维表面的稳定性、重构等方面取得了显著的成果。在国际知名期刊J. Am. Chem. Soc.、Angew. Chem. Int. Ed.、Adv. Mater., Adv. Funct. Mater.,Nanoscale等发表SCI论文50余篇,引用1700余次,H因子20。成果多次被Phys.Org、Nanowerk等国际科技媒体报道。获得2014年辽宁省优秀博士学位论文奖, 入选2015年博士后资助选介(全国总100人),2018年入选第十四批千人计划青年项目

研究方向

   1、 衬底表面支撑团簇的结构、稳定性和演化

  2、 低维材料表面的结构、稳定性和重构。

  3、 二维材料边结构、重构。

  4、 MD/kMC等多尺度模拟材料的生长行为。

  5、 材料的物化性质、以及其在电子、光电、催化等应用。

科研项目

   1、青年千人项目 , 主持

   2、基金委青年基金项目 主持已完成

   3、博士后面上一等资助  主持已完成

   4、博士后特别资助         主持已完成

   5、中国工程物理研究院发展基金  主持已完成

荣誉奖励

   1、入选十四批青年千人

   2、2015 入选中国博士后基金资助者选介(100人)

   3、2014 辽宁省优秀博士学位论文

   4、2019 大连理工大学“课程思政”青年骨干教师

近期代表性论文


1.   Junfeng Gao*, Anna Cupolillo*, Silvia Nappini, Federica Bondino, Raju Edla, Vito Fabio, Raman Sankar, Yong-Wei Zhang*, Gennaro Chiarello, Antonio Po litano*, Surface Reconstruction, Oxidation Mechanism, and Stability of Cd3As2 Advanced Functional Materials 29, 1900965 (2019).

2.  Yao Sun+(共同一作), Junfeng Gao+(共同一作), Yuan Cheng*, Yong-Wei Zhang, Kaiyang Zeng*, Design of the Hybrid Metal–Organic Frameworks as Potential Supramolecular Piezo-/Ferroelectrics The Journal of Physical Chemistry C 123, 3122 (2019).

3.   Shuai Chen+(共同一作), Junfeng Gao+(共同一作), Bharathi M Srinivasan, Gang Zhang, Viacheslav Sorkin, Ramanarayan Hariharaputran, Yong-Wei Zhang*, Origin of ultrafast growth of monolayer WSe 2 via chemical vapor deposition npj Computational Materials 5, 28 (2019).

4.   Ziyu Hu, Junfeng Gao*, Shengli Zhang, Jijun Zhao, Wenhan Zhou, and Haibo Zeng. Topologically protected states and half-metal behaviors: Defect-strain synergy effects in two-dimensional antimoneneraphene. Phys. Rev. Materials. 3, 07400533 (2019).


5.   Junfeng Gao, Joanne Yip, Jijun Zhao, Boris I. Yakobson, Feng Ding*. Graphene Nucleation on Transition metal surface: Structure Transformation and Role of the Metal Step Edge. J. Am. Chem. Soc. 133, 5009-5015 (2011).

6.   Junfeng Gao, Jijun Zhao*, Feng Ding*. Transition Metal Surface Passivation Induced Graphene Edge Reconstruction. J. Am. Chem. Soc. 134, 6204-6209 (2012).

7.   Qinghong Yuan+, Junfeng Gao+(共同一作), Haibo Shu+, Jijun Zhao*, Xiaoshuang Chen*, Feng Ding*. Magic Carbon Clusters in the Chemical Vapor Deposition Growth of Graphene. J. Am. Chem. Soc. 134, 2970-2975 (2012).

8.   Junfeng Gao, Gang Zhang*, and Yong-Wei Zhang*. The Critical Role of Substrate in Stabilizing Phosphorene Nanoflake: A Theoretical Exploration. J. Am. Chem. Soc. 138, 4763–4771 (2016).

9.   Junfeng Gao, Feng Ding*. The Structure and Stability of Magic Carbon Clusters Observed in Graphene Chemical Vapor Deposition Growth on Ru(0001) and Rh(111) Surfaces. Angew. Chem. Int. Ed. 53, 14031 (2014).

10.   Nannan Han, Hongsheng Liu, Junfeng Zhang, Junfeng Gao* and Jijun Zhao*. Atomistic understanding of the lateral growth of graphene from the edge of an h-BN domain: towards a sharp in-plane junction. Nanoscale 9, 3585-3592 (2017).

11.   Junfeng Gao, Junfeng Zhang, Hongsheng Liu, Qinfang Zhang, Jijun Zhao*. Structures, mobilities, electronic and magnetic properties of point defects in silicene. Nanoscale 5, 17695-17703 (2013).ESI 高被引)

12.    Junfeng Gao, Xiangjun Liu, Gang Zhang, Yong-Wei. Nanotube-terminated zigzag edges of phosphorene formed by self-rolling reconstruction. Nanoscale 8, 17940-17946 (2016).

13.  Junfeng Gao, Gang Zhang*, and Yong-Wei Zhang*. Vastly enhancing the chemical stability of phosphorene by employing an electric field. Nanoscale  9, 4219-4226 (2017).

14. Nannan Han, Hongsheng Liu, Junfeng Zhang, Junfeng Gao* and Jijun Zhao. Atomistic understanding of the lateral growth of graphene from the edge of an h-BN domain: towards a sharp in-plane junction. Nanoscale 9, 3585-3592 (2017).

15.     Xiangjun liu+, Junfeng Gao+(共同一作), Gang Zhang*, and Yong-Wei Zhang. MoS2-graphene in-plane contact for high interfacial thermal conduction. Nano Res. doi:10.1007/s12274-017-1504-8 (2017).

16.     Junfeng Gao+, Ziwei Xu+, Shuai Chen+, Madurai S Bharathi+, Yong-Wei Zhang*, Computational Understanding of the Growth of 2D Materials Advanced Theory and Simulations 1, 1800085 (2018).

17.     Junfeng Gao, Gang Zhang, Boris I Yakobson, Yong-Wei Zhang, Kinetic theory for the formation of diamond nanothreads with desired configurations: a strain–temperature controlled phase diagram Nanoscale 10, 9664-9672 (2018).

18.     Xiangjun Liu, Junfeng Gao, Gang Zhang, YongWei Zhang. Unusual Twisting Phonons and Breathing Modes in TubeTerminated Phosphorene Nanoribbons and Their Effects on Thermal Conductivity. Advanced Functional Materials 27, 1702776 (2017).

19.     Junfeng Gao, Jijun Zhao*. Initial geometries, interaction mechanism and high stabliliy of silicene on Ag(111) surface. Sci. Rep. 2, 861 (2012).

20.     Junfeng Gao, Qinghong Yuan, Hong Hu, Jijun Zhao*, Feng Ding*. Formation of Carbon Clusters in the Initial Stage of Chemical Vapor Deposition Graphene Growth on Ni(111) Surface. J. Phys. Chem. C 115, 17695 (2011).

21.     Junfeng Gao, Feng Ding*. First-principles Phase Diagram of Magic Sized Carbon Clusters on Ru (0001) and Rh (111) Surfaces. J. Phys. Chem. C, 119, 11086–11093 (2015).

22.     Junfeng Gao, Jijun Zhao*. Carbon Clusters Near the Step of Rh Surface: implication for the initial stage of graphene nucleation. Eur. Phys. J. D 67, 50 (2013).

23.     Junfeng Gao, Feng Ding*. The Study on the Medium-Sized Carbon Islands on Ru (0001) Surface. J. Cluster. Sci. 26, 347-360 (2015).

24.     Qinghong Yuan, Hong Hu, Junfeng Gao, Feng Ding*, Zhifeng Liu, Boris I. Yakobson*. Upright Standing Graphene Formation on Substrates. J. Am. Chem. Soc. 133, 16072-16079 (2011).

25.     Yubin Chen, Jingyu Sun, Junfeng Gao, et al. Growing Uniform Graphene Disks and Films on Molten Glass for Heating Devices and Cell Culture Adv. Mater. 27, 7839–7846 (2015).

26.     Fen Li, Junfeng Gao, Jian Zhang, Fen Xu, Jijun Zhao*, Lixian Sun*. Graphene oxide and lithium amidoborane: a new way to bridge chemical and physical approaches for hydrogen storage. J. Mater. Chem. A 1, 8016-8022 (2013).


  

近期会议邀请报告

      1、2019 新加坡,International Conference on Materials for Advanced Technologies, 邀请报告,FF分会主席

      2、2019 香港 ,XXXI IUPAP Conference on Computational Physics, 邀请报告

      3、2019 杭州, 全国半导体大会,邀请报告

      4、2019  成都, 中国材料大会,  邀请报告

      5、2019  青岛,第十二届计算纳米科学与新能源材料国际研讨会, 邀请报告

        6、2018  大连,秋季物理年会,M分会 邀请报告, M分会主席

        7、2018  天津,中国(国际)功能材料科技与产业高层论坛 邀请报告

      8、2016  青岛,17届亚太材料大会分会,邀请报告:,z分会主席


   





纳米团簇结构和性质
  • 二维材料稳定性,生长机理
  • 计算物理
    计算纳米材料

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