个人简述:

杨叶锋，男，工学博士，硕士生导师，美国化学会会员，中国化学会会员。2006年本科毕业于浙江大学材料科学与工程学系，获工学学士学位；2011年研究生毕业于浙江大学硅材料国家重点实验室，获工学博士学位；2013年9月进入浙江理工大学材料与纺织学院工作；2017年2月起，借调到科技部中国科学技术交流中心工作。曾获得浙江大学最高荣誉竺可桢奖学金和奖章、浙江大学十大“求是学术之星”，浙江大学Renesola青年才俊奖学金、浙江大学优秀共产党员、优秀研究生干部、浙江省优秀毕业生等荣誉；作为主要成员曾参与国家科技部“973”以及多项国家自然科学基金项目，并获得浙江省科技一等奖。

主要从事功能纳米材料在能源与环境领域的应用与基础研究；目前主持国家自然科学青年基金、浙江理工大学“521”中青年骨干人才等多个项目；应邀赴美国洛杉矶、费城、中国香港、北京、武汉、天津、南京等地出席American Chemical Society会议、IEEE INEC纳电子会议、中美华人纳米论坛等材料领域学术会议并做相关报告；迄今为止以第一或通讯作者在J. Am. Chem. Soc.、Nanoscale、J. Mater. Chem. A、RSC Adv.、CrystEngComm(封面)、Electrochim. Acta、Cryst. Growth & Design等材料领域国际学术期刊上发表多篇SCI论文，担任SCI期刊J. Nanomater.的Guest editor以及多个学术期刊如ACS Appl. Mater. & Interfaces、ACS Sutainable Chemistry & Engineering、Electrochim. Acta、RSC adv.、New J. Chem.、J. Alloys Comp.、Appl. Surf. Sci.等的特邀审稿人。

科研工作:

代表性论文：

18.Ziyue Zhan,Shaojie Chen,Jinlei Xie,YefengYang*,Jie Xiong*,Journal of Alloys and Compounds, 722, 928-937, 2017 (影响因子3.133)

17.Shaojie Chen,Yefeng Yang*, Ziyue Zhan, Jinlei Xie and Jie Xiong*,RSC Advance,7, 18447-18455,2017(影响因子3.289，本科生一作)

16. Yiran Zhang,Yefeng Yang*,Lingxiao Mao,Ding Cheng, Ziyue Zhanand Jie Xiong*,Materials Letters, 182, 298-301,2016(影响因子2.437，本科生一作)

15. Yefeng Yang*, Ding Cheng, Shaojie Chen, Yingli Guan, and Jie Xiong*, Electrochimica Acta, 193, 116-127,2016(影响因子4.504， 引用5次)

14. Yu Liu* andYefeng Yang*,Journal of Nanomaterials, 2016, 8123652,2016 (Review paper, 影响因子1.644)

13. Jinlei Xie,Yefeng Yang*, Haiping He, Ding Cheng, Minmin Mao, Qinxu Jiang, Lixin Song and Jie Xiong*,Applied Surface Science, 355,921-929,2015(影响因子2.711，本科生一作，引用4次)

12. Ding Cheng,Yefeng Yang*, Yaobin Luo, Changjiang Fang and Jie Xiong*,Electrochimica Acta, 176, 1343-1351,2015(影响因子4.504，引用7次)

11. Yaguang Li, Liping Zhu,Yefeng Yang, Hui Song, Zirui Lou, Yanmin Guo and Zhizhen Ye,Small, 11, 871-876,2015(影响因子8.368)

10. Ding Cheng,Yefeng Yang*, Jinlei Xie, Changjiang Fang, Guoqing Zhang and Jie Xiong*,Journal of Materials Chemistry A, 3, 14348-14357,2015(影响因子7.443，引用23次)

9. Pan Hu,Yefeng Yang, Yiyin Mao, Junwei Li, Wei Cao, Yulong Ying, Yu Liu, Jiahuan Lei and Xinsheng Peng,CrystEngComm, 17, 1576-1582,2015(影响因子4.034)

8. Lixin Song, Qingxu Jiang, Pingfan Du,Yefeng Yang, Jie Xiong and Can Cui,Journal of Power Sources, 261, 1-6,2014(影响因子6.217)

7. Yefeng Yang, Yaguang Li, Liping Zhu, Haiping He, Liang Hu, Jingyun Huang, Fengchun Hu, Bo He and Zhizhen Ye,Nanoscale, 5, 10461-10471,2013(影响因子7.394，引用26次)

6. Zhong Chen, Jingyun Huang,Yefeng Yang, Ye Wang, Yongjun Wu, Haiping He, Xiaoyan Wei, Zhizhen Ye, Huarong Zeng and Honglin Cong,RSC Advances, 2, 7380-7383,2012(影响因子3.84)

5. Yefeng Yang, Yizheng Jin, Haiping He, Qingling Wang, Yao Tu, Huanming Lu and Zhizhen Ye,Journal of the American Chemical Society, 132, 13381-13384,2010(影响因子12.113，引用107次)

4. Yefeng Yang, Yizheng Jin, Haiping He and Zhizhen Ye,CrystEngComm, 12, 2663-2665,2010(影响因子4.034，封面论文，引用12次)

3. Qingling Wang,Yefeng Yang, Haiping He, Dongdong Chen, Zhizhen Ye and Yizheng Jin,Nanoscale Research Letters, 5, 882-888,2010(影响因子2.779)

2. Yefeng Yang, Yinzhu Zhang, Yizheng Jin, Zhizhen Ye, Jianguo Lu, Haiping He, Jingyun Huang, Liping Zhu and Binghui Zhao,Crystal Growth & Design, 9, 5043-5048,2009(影响因子4.891)

1. Yefeng Yang, Zhizhen Ye, Jianguo Lu, Haiping He, Yizheng Jin, Jingyun Huang, Jinrui Wang, Minxia Qiu and Binghui Zhao,Journal of Physics D: Applied Physics, 41, 115410, 2008 (影响因子2.721)

学术会议：

7. Yefeng Yang, et al., CICE 2016 (第四届中国国际静电纺丝大会), Beijing, 2016.

6. Yefeng Yang, et al., 252ndACS National Meeting & Exposition,Philadelphia, Pennsylvania,USA, 2016.(Oral)

5. Yefeng Yang, et al., 11thSino-US Symposium on Nanoscale Science and Technology, Nanjing, China, 2016.(Poster)

4. Yefeng Yang, et al., 10thSino-US Symposium on Nanoscale Science and Technology, Wuhan, China, 2015. (Poster)

3. Yefeng Yang, et al., ZSTU-UBC International Workshop on Advanced Fibrous Materials, Hangzhou, China, 2014. (Oral)

2.Yefeng Yang, et al., 3rd IEEE International Nanoelectronics Conference, Hong Kong, China, 2010. (Poster)

1. Yefeng Yang, et al., 241stACS National Meeting & Exposition, Los Angeles, California, USA, 2010. (Oral)

10.We report a novel electrode of 3D hierarchical Co3O4@NiMoO4flower-like hybrid arrays synthesized with the combination of hydrothermal and post-annealing treatment. The Co3O4nanowire arrays are utilized as scaffolds and interconnected NiMoO4nanosheets are grown on the surface. The assembled hybrid supercapacitor device based on Co3O4@NiMoO4and AC as the positive and negative electrodes can achieve a high energy density of 58.5 Wh/kg at 389 W/kg, suggesting the great potential for applications in supercapacitors.

9.This review is specifically focused on the recent progress in enhancing the LIBs performance of TiO2based materials with various synthetic strategies and architecture control, including designing hollow structure togenerate more open channels and active sites for Li-ion transport, coating or combining TiO2with metal to improve its electronic conductivity, or incorporating carbonaceous materials such as activated carbon, CNTs,or graphene to enhancethe capacity and cycling stability.

8.A novel electrode of three-dimensional (3D) hierarchical NiCo2S4@Ni(OH)2core-shell hybrid nanosheet arrayswasfabricated forsupercapacitors. The HSC device based on the above materials exhibits high energy density (53.3 Wh/kg at 290W/kg), high power density (6420W/kg at 32.1 Wh/kg), as well as excellent cycling stability (98.8% over 2000 cycles at 20mA/cm2), suggesting the great potential of this hybrid nanostructure as promising electrode materials for high-performance supercapacitors.

7. A simple two-step method is reported for the synthesis of ternary Ni-Mo oxide.The3D interconnected networks of Ni-Mo oxide nanosheets are gown on Ni foam.The ultrathin and mesoporous features are revealed by HRTEM and STEM.The nanosheets are tested as supercapacitor electrodes with enhanced properties.

6.Hierarchical NiCo2O4@NiMoO4core-shell nanowire/nanosheet arrays were successfully fabricated and assembled in an asymmetric supercapacitor device withoutstanding electrochemical performance.

5.We report a novel hierarchical Ag3PO4/TiO2nanofiber heterostructure. The heterostructure was prepared by electrospinning and solution processes.The resulting hybrid exhibited enhanced visible light photocatalytic activities. The hybrid system enabled full utilization of solar light and less consumption of Ag. This approach is general for the design and construction of hybrid photocatalysts.

4.Here we report a facile and green synthetic approach for high-quality colloidal Mn doped ZnO NCs with simultaneous control over composition, shape and optical properties. Specifically, the shape of doped ZnO NCs can be finely modulated from three dimensional (3D) tetrapods to 0D spherical nanoparticles in a single reaction scheme. The growth mechanism of doped ZnO NCs with interesting shape transition is explored.

3. Here we show that in addition to altering the atomic composition of the nanocrystals the introduction of specific dopants can also lead to dramatic changes in morphology. The creation of Mg-doped ZnO nanocrystals provides an excellent example of this procedure depending on the molar ratio of dopant precursor in the reagents, doped nanocrystals with well-defined shapes, from tetrapods to ultrathin nanowires, which exhibit tunable optoelectronic properties, are obtained for the first time.

2.High quality ultrathin CeO2nanorods were synthesized through an oriented attachment process followed by ripening.

1. Quasi-aligned (Zn,Cd)O nanorods with highly faceted morphology were synthesized by a simple catalyst-free thermal evaporation method. The crystal structure and optical properties of the as-synthesized nanorods were thoroughly investigated. The results indicate that the (Zn,Cd)O nanorods are single crystals of wurtzite structure, having 12 side planes, namely, {011̅0} and {112̅0} planes. The presence of Cd is essential for obtaining these highly faceted nanorods.

浙江理工大学优秀班主任（2015）；

协助指导研究生获浙江理工大学健盛卓越奖学金（2015）；

指导本科生获得浙江省新苗人才计划（2016）一项；

指导本科生获得国家级大学生创新创业训练计划（2016）一项；

浙江理工大学本科毕业论文优秀指导教师（2016）；

协助指导研究生获国家奖学金（2016）。

欢迎喜欢科研、追求卓越的优秀本科生、研究生加盟。