王岩

2021年03月16日 19:25  点击:[]

基本信息

姓名: 王岩                                                                                                       出生年月:19856

学历: 博士研究生                                                                                            学院: 188金宝慱亚洲体育官网

职称: 教授                                                                                                    联系方式:wangy@xatu.edu.cn   450767149@qq.com

学习经历

20089-20147月:西北工业大学,材料学,博士

20049-20087月:西安石油大学,化学工程与工艺,学士

工作经历

201912-至今:西安工业大学  教授

201812-201912月:西安工业大学  副教授

20146-201812月: 西安工业大学   讲师 

教育教学

主讲课程:《化工原理》、《CAD制图》、《聚合物合成工艺学》、《聚合物基复合材料》、《化工设计》

招生信息

每年招收硕士生3-4

研究方向

1)吸波、电磁屏蔽材料;(2)光电磁材料;(3)柔性电子器件

学术成果

获奖及荣誉

1)陕西省青年科技新星,2018

2)西安工业大学优秀青年教师奖励基金,2018

3)西安工业大学优秀教师,2017年,2020

3)陕西高等学校科学技术二等奖,2018

4)西安工业大学科技进步特等奖,2017

科研项目

(1)  国家自然科学青年基金:新型多孔石墨烯基复合材料的电磁调控机制与吸波机理研究,(编号:61701386),24

(2)  陕西省自然科学基金:导电聚合物/MOF结构共修饰石墨烯的电磁调控机制,(编号:2017JQ5060),3

(3)  陕西省青年科技新星项目:三维石墨烯气凝胶基多元复合材料的制备及吸波机理研究,(编号:2019KJXX-033),10

(4)  高温固化环氧碳纤维复合材料耐热性及韧性测试与分析,  8   

(5)  国家自然科学面上基金:基于纳米层离作用的二维层状电极材料间层组装机理和储能机制,(编号:21975196),60

发表文章

第一作者或通讯作者发表SCI收录论文40余篇,其中ESI热点论文4篇、ESI高被引论文7

[1] Yan Wang,* Xiang Gao, Xinming Wu, et al. Facile design of 3D hierarchical NiFe2O4/N-GN/ZnO composite as a high performance electromagnetic wave absorber. Chemical Engineering Journal. 2019, 375: 121942. (ESI热点论文)

[2] Yan Wang,* Xiang Gao, Yuqiao Fu, et al. Enhanced microwave absorption performances of polyaniline/graphene aerogel by covalent bonding. Composites Part B. 2019, 169: 221-228. (ESI 高被引论文)

[3] Xiaochuang Di, Yan Wang,* Yuqiao Fu, et al. Wheat flour-derived nanoporous carbon@ZnFe2O4 hierarchical composite as an outstanding microwave absorber. Carbon. 2021, 173: 174-184.

[4] Yan Wang,* Xiaochuang Di, Xiang Gao, et al. Design of MOF-derived hierarchical Co@C@RGO composite with controllable heterogeneous interfaces as a high-efficiency microwave absorbent. Nanotechnology. 2020, 31: 395710-395720.

[5] Yan Wang,* Xiaochuang Di, Zhao Lu, et al. Rational construction of hierarchical Co@C@NPC nanocomposites derived from bimetallic hybrid ZIFs/biomass for boosting the microwave absorption. Journal of Colloid and Interface Science. 2021, 589: 462-471. 

[6] Yan Wang,* Xiaochuang Di, Yuqiao Fu, et al. Facile synthesis of the three- dimensional flower-like ZnFe2O4@MoS2 composite with heterogeneous interfaces as a high-efficiency absorber. Journal of Colloid and Interface Science. 2021, 587: 561- 573. 

[7] Yan Wang,* Xiaochuang Di, Xinming Wu, et al. MOF-derived nanoporous carbon/Co/Co3O4/CNTs/RGO composite with hierarchical structure as a high- efficiency electromagnetic wave absorber. Journal of Alloys and Compounds. 2020, 846: 156215-156225.  

[8] Yan Wang,* Xiang Gao, Lijuan Zhang, et al. Synthesis of Ti3C2/Fe3O4/PANI hierarchical architecture composite as an efficient wide-band electromagnetic absorber. Applied Surface Science. 2019, 480: 830-838. (ESI热点论文)

[9] Yan Wang,* Xinming Wu, Wenzhi Zhang, et al. Fabrication of flower-like Ni0.5Co0.5(OH)2@PANI and its enhanced microwave absorption performances. Materials Research Bulletin. 2018, 98: 59-63. (ESI热点论文)

[10] Yan Wang,* Wenzhi Zhang, Xinming Wu, et al. Conducting polymer coated metal-organic framework nanoparticles: Facile synthesis and enhanced electromagnetic absorption properties. Synthetic Metals. 2017, 228: 18-24. (ESI 高被引论文)

[11] Yan Wang,* Xiang Gao, Chenghao Lin, et al. Metal organic frameworks-derived Fe-Co nanoporous carbon/graphene composite as a high-performance electromagnetic wave absorber. Journal of Alloys and Compounds. 2019, 785: 765-773. (ESI热点论文)

[12] Yan Wang,* Yuqiao Fu, Xinming Wu, et al. Synthesis of hierarchical core-shell NiFe2O4@MnO2 composite microspheres decorated graphene nanosheet for enhanced microwave absorption performance. Ceramics International. 2017, 43 (14): 11367-11375. 

[13] Yan Wang,* Xiang Gao, Wenzhi Zhang, et al. Synthesis of hierarchical CuS/RGO/PANI/Fe3O4 quaternary composite and enhanced microwave absorption performance. Journal of Alloys and Compounds. 2018, 757: 372-381.

[14] Yan Wang,* Xinming Wu, Wenzhi Zhang, et al. Synthesis of polyaniline nanorods and Fe3O4 microspheres on graphene nanosheets and enhanced microwave absorption performances.Materials Chemistry and Physics. 2018, 209: 23-30.

[15] Yan Wang,* Xinming Wu, Wenzhi Zhang, et al. Synthesis and high-performance microwave absorption of graphene foam/polyaniline nanorods. Materials Letters. 2016, 165: 71-74.

[16] Yan Wang,* Wenzhi Zhang, Xinming Wu, et al. Metal-organic framework nanoparticles decorated with graphene: A high-performance electromagnetic wave absorber. Journal of Magnetism and Magnetic Materials. 2016, 416: 226-230. 

[17] Yan Wang,* Xiang Gao, Hongwei Zhou, et al. Fabrication of biomass-derived carbon decorated with NiFe2O4 particles for broadband and strong microwave absorption. Powder Technology. 2019, 345: 370-378.

[18] Xiang Gao, Yan Wang,* Qiguan Wang, et al. Facile synthesis of a novel flower-like BiFeO3 microspheres/graphene with superior electromagnetic wave absorption performances. Ceramics International. 2019, 45: 3325-3332.

[19] Xiang Gao, Yan Wang,* Qiguan Wang, et al. Facile synthesis of hollow cube-like ZnSnO3 wrapped by nitrogen-doped graphene: As a high-performance and enhanced synergistic microwave absorber, Journal of Magnetism and Magnetic Materials. 2019, 486: 165251.   

[20] Yan Wang,* Yanbo Chen, Xinming Wu, et al. Fabrication of MoS2-graphene modified with Fe3O4 particles and its enhanced microwave absorption performance, Advanced Powder Technology. 2018, 29: 744-750.

[21] Yan Wang,* Wenzhi Zhang, Chunyan Luo, et al. Synthesis, characterization and enhanced electromagnetic properties of NiFe2O4@SiO2-decorated reduced graphene oxide nanosheets, Ceramics International. 2016, 42: 17374-17381.

[22] Yan Wang,* Wenzhi Zhang, Chunyan Luo, et al. Fabrication and high-performance microwave absorption of Ni@SnO2@PPy Core-Shell composite, Synthetic Metals. 2016, 220: 347-355.

[23] Yan Wang,* Xinming Wu, Wenzhi Zhang, et al. Fabrication and enhanced electromagnetic wave absorption properties of sandwich-like graphene@NiO@ PANI decorated with Ag particles, Synthetic Metals. 2017, 229: 82-88.

[24] Yan Wang,* Xinming Wu, Wenzhi Zhang, et al. 3D heterostructure of graphene@Fe3O4@WO3@PANI: Preparation and excellent microwave absorption performance, Synthetic Metals. 2017, 231: 7-14.

[25] Yan Wang,* Xinming Wu, Wenzhi Zhang, et al. Facile synthesis of Ni/PANI/RGO composites and their excellent electromagnetic wave absorption properties, Synthetic Metals. 2015, 210: 165-170.

[26] Yan Wang,* Hongyu Zhu, Yanbo Chen, et al. Design of hollow ZnFe2O4 microspheres@graphene decorated with TiO2 nanosheets as a high-performance low frequency absorber, Materials Chemistry and Physics. 2017, 202: 184-189.   

[27] Yan Wang,* Xiang Gao, Xinming Wu, et al. Hierarchical ZnFe2O4@RGO@CuS composite: Strong absorption and wide-frequency absorption properties, Ceramics International. 2018, 44: 9816-9822.

[28] Yan Wang,* Wenzhi Zhang, Chunyan Luo, et al. Superparamagnetic FeCo@SnO2 nanoparticles on graphene-polyaniline: Synthesis and enhanced electromagnetic wave absorption properties, Ceramics International. 2016, 42: 12496-12502.

[29] Yan Wang,* Xinming Wu, Wenzhi Zhang, et al. Synthesis of ferromagnetic sandwich FeCo@graphene@PPy and enhanced electromagnetic wave absorption properties, Journal of Magnetism and Magnetic Materials. 2017, 443: 358-365.  

[30] Yan Wang,* Xinming Wu, Wenzhi Zhang, et al. Synthesis and electromagnetic absorption properties of Ag-coated reduced graphene oxide with MnFe2O4 particles, Journal of Magnetism and Magnetic Materials. 2016, 404: 58-63.

授权专利

[1]  王岩;高翔;吴新明;王奇观;张文治;罗春燕. 共价键结合聚苯胺纳米棒-石墨烯气凝胶吸波材料及其制备方法. 专利号: ZL201810906451.X

[2]  黄英;王岩;张伟,王科,吴海伟,桑易斯. 一种石墨烯/Ni0.8Zn0.2Ce0.06Fe1.94O4纳米吸波材料的制备方法. 专利号:ZL201310382909.3

[3]  黄英;王秋芬;赵阳;王科;王岩;丁娟;张伟;宗蒙. 锂离子电池用硫化锡/稀土金属负极材料的制备方法. 专利号:ZL201210437703.1

[4]  黄英;王秋芬;赵阳;王岩;姚文慧;宗蒙. 聚合物掺杂锡酸锂负极材料的制备方法. 专利号:ZL 201110456611.3

 

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地址:陕西省西安市未央大学城学府中路2号 邮编:710021   电话:029-86173326  86173324(本科招生专线)   版权所有:西安工业大学188金宝慱亚洲体育官网
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