职  称:副教授
研究方向:功能纳米材料
办公电话:0431-85099657
办公地点:化学楼331

个人简历

在纳米结构导电聚合物的制备与应用、导电聚合物与金属、金属氧化物材料的复合、表面活性剂调控下纳米材料的合成等方面开展了大量的工作,取得了一定的成果。以第一或通讯作者在J. Am. Chem. Soc., Chem. Commun., J. Mater. Chem.等期刊上发表SCI学术论文40余篇;出版“纳米结构导电聚合物研究进展”书籍一部;参与编写“Advanced Nanomaterials for Electrochemical Energy Conversion and Storage”第10章“Nanomaterials of conducting polymers and its application in energy conversion and storage”;关于纳米结构金属/导电聚合物复合材料的构建与性能研究的系列论文获得吉林省自然科学学术成果奖一等奖。 教育经历: 2003/09 - 2007/07,吉林大学,物理化学,博士 2000/09 - 2003/06,东北师范大学,物理化学,硕士 1996/09 - 2000/07,东北师范大学,化学教育,学士 工作经历: 2011/12 - 至今,东北师范大学,化学学院,副教授 2008/03 – 2010/03,新加坡南洋理工大学,化学与生物化学系,博士后 2006/07 - 2011/11,东北师范大学,化学学院,讲师 2001/07 - 2006/06,东北师范大学,化学学院,助教 教改论文: 2024: 邢双喜*,李艳梅,张天翊,王春刚,在物理化学课程中培养大学生逻辑思维能力的探索与实践,化学教育(中英文), 2024, 45(6):11-15. 2023: 邢双喜*, 郑龙. 大学化学习题课的困境与有效教学策略, 化学教育(中英文), 2023, 44(6):24-28. 邢双喜,科学家故事融入物理化学课堂的新模式探索,大学(教学与教育),2023,5,587:100-103. 邢双喜,张素铭,孙启明,大学物理化学课程中逻辑思维能力的培养示例,2023,51(13):215-217. 2022: 邢双喜*,张素铭,周仕东,自拟试题在物理化学课程学习中的实践探索,化学教育(中英文). 2022, 43 (2): 51-56. 2021: 张素铭,邢双喜*, 对如何促进学生学好物理化学网络课程的思考,化学教育(中英文),2021,42 (4), 40-45. 2020: 邢双喜,王一鸣,张育新,基于师生问答模式下的物理化学教学效果提升研究,大学(教学与教育),2020,482,94-95. 2019: 邢双喜*,王一鸣,物理化学教材中表格数据的深度分析与教学实践-以电解质溶液一章为例,大学化学,2019,34(2),65-69. 2016: 邢双喜,孙文东*,从熵的角度解读凝固点降低公式,大学化学,2016,31(12),83-85. 科研论文: 2023: 1. Mengmeng Hou#,Kai Chen#, Guodong Zhang**, Xinyu Liang, Xingfa Liu, Shuangxi Xing*, 3D conductive molecular framework derived MnO2/N, P co-doped carbon as sulfur hosts for high-performance lithium-sulfur batteries,J. Energy Storage, 72, 2023, 108339.(IF:9.400) 2. Mengmeng Hou, Huiling Gu, Ji Huang, Hongtao Guan*, Shuangxi Xing*,Three-dimensional polyaniline/cerium oxide composite aerogel with enhanced microwave absorption properties, Synth. Met., 2023, 293, 117251. (IF:4.000) 3. Yitong Liu#, Yiwei Zhao#, Yuanqing Zhang, Shuangxi Xing*, Hierarchical three-dimensional CoNi LDH‐Ni3S2 supported on Ni foam as a stable and efficient electrocatalytic material for overall water splitting, Electroanalysis, 2023, 35, 202200251.(IF:3.077) 2022: 1. Yiwei Zhao, Qiming Sun, Xianchun Liu, Dehua Li*, Shuangxi Xing*, Cu/Co/CoS2 embedded in S,N doped carbon as highly-efficient oxygen reduction and evolution electrocatalyst for rechargeable zinc-air batteries, Inorg. Chem. Front., 2022, 9, 2917 - 2927.(IF: 7.779) 2. Yuqi Liu#, Yitong Liu#, Yue Yu, Chengzhan Liu, Shuangxi Xing*, Facile route to achieve MoSe2-Ni3Se2 on nickel foam as efficient dual functional electrocatalysts for overall water splitting, Front. Energy, 2022, 16 (3), 483-491.(IF:2.964) 3. Yiwei Zhao, Yue Yu, Yuanhong Wang, Jicheng Ma, Shuangxi Xing*, Facile route to synthesize Cu, S, N-doped carbon as highly efficient and durable electrocatalyst towards oxygen reduction reaction, Catal. Lett., 2022, 152, 2342–2351. (IF:2.936) 4. Qiming Sun, Yiwei Zhao, Xiaodan Yu, Chao Zhang*, Shuangxi Xing*, Interface engineering of CoO/N-doped carbon nanomaterials as a bifunctional electrocatalyst for rechargeable zinc-air batteries, J. Electrochem. Soc., 169, 6, 060537. (IF:4.316) 5. 郭锦锐,李金龙,邢双喜*,聚多巴胺包覆银衍生氧还原电催化剂的合成,分子科学学报,第38卷第4期,342-350. 2021: 1. 杨钦,于跃,邢双喜*,基于镍/氮掺杂碳复合材料的双功能电催化剂合成及电化学性能研究,化学研究与应用,第33卷第3期,486-492. 2. Usman Ali, Kamran Sohail, Yuqi Liu, Xiaodan Yu, Shuangxi Xing*, Molybdenum and phosphorous dual-doped, transition metal-Based, free-standing electrode for overall water splitting, ChemElectroChem, 2021, 8, 1612-1620.(IF: 4.782) 2020: 1. Jinrui Guo, Yue Yu, Jicheng Ma, Tingting Zhang, Shuangxi Xing*, Facile route to achieve N, S-codoped carbon as bifunctional electrocatalyst for oxygen reduction and evolution reactions, J. Alloy. Compd., 2020, 821, 153484.(IF: 5.316) 2. Mingjun Ji, Bing He, Yue Yu, Xiaodan Yu, Shuangxi Xing*, CeO2 encapsulated by iron, sulfur, and nitrogen-doped carbons for enhanced oxygen reduction reaction catalytic activity, ChemElectroChem, 2020, 7, 642–648.(IF: 4.590) 3. Usman Ali, Yue Yu, Jinrui Guo, Yuqi Liu, Zhongcheng Mu, Shuangxi Xing*, Facile route to achieve Co@Mo2C encapsulated by N-doped carbon as efficient electrocatalysts for overall water splitting in alkaline media, J. Electrochem. Soc., 2020, 167, 044520. (IF: 4.316) 4. Yue Yu, Yuqi Liu, Xiaolei Peng, Xianchun Liu, Yan Xing**, Shuangxi Xing*, Multi-shelled CeO2/Co@N-doped hollow carbon microsphere as trifunctional electrocatalyst for rechargeable zinc-air battery and overall water splitting, Sustainable Energy Fuels, 2020, 4, 5156 - 5164. (IF: 6.367) 5. Yuqi Liu, Yue Yu, Zhongcheng Mu, Yuanhong Wang, Usman Ali, Shengyu Jing, Shuangxi Xing*, Urea-assisted enhanced electrocatalytic activity of MoS2-Ni3S2 for overall water splitting, Inorg. Chem. Front., 2020, 7, 3588–3597.(IF: 6.569) 2019: 1. Liang Zhang, Xinyue Wang, Tingting Zhang, Chengzhan Liu, Dehua Li, Shuangxi Xing*, Achieving Janus Ag@N-doped carbon for oxygen reduction reaction from eccentric encapsulated Ag@polypyrrole, J. Alloy. Compd., 2019, 785, 491-498.(IF: 4.650) 2. Guodong Zhang, Yanhong Shi, Hongru Wang, Lingling Jiang, Xiaodan Yu, Shengyu Jing**, Shuangxi Xing*, Panagiotis Tsiakaras***, A facile route to achieve ultrafine Fe2O3 nanorods anchored on graphene oxide for application in lithium-ion battery, J. Power Sources, 2019, 416, 118-124.(IF: 8.247) 3. Tingting Zhang, Liang Zhang, Xianchun Liu, Zhongcheng Mu, Shuangxi Xing*, Achieving nitrogen-doped carbon/MnO2 nanocomposites for catalyzing the oxygen reduction reaction, Dalton Transactions, 2019, 48, 3045-3051. (IF: 4.174) 4. Yue Yu, Xiaolei Peng, Usman Ali, Xianchun Liu, Yan Xing**, Shuangxi Xing*, Facile route to achieve bifunctional electrocatalysts for oxygen reduction and evolution reactions derived from CeO2 encapsulated by the zeolitic imidazolate framework-67, Inorg. Chem. Front., 2019, 6, 3255-3263. (IF: 5.958) 5. Lingling Jiang, Guodong Zhang, Dehua Li, Chengzhan Liu, Shuangxi Xing*, One-pot achievement of MnO2/Fe2O3 nanocomposites for the oxygen reduction reaction with enhanced catalytic activity, New J. Chem.,2019, 43, 16870-16875. (IF: 3.288) 2018: 1. Yue Yu, Bowen He, Yujia Liao, Xiaodan Yu, Zhongcheng Mu, Yan Xing*, Shuangxi Xing*, Preparation of hollow CeO2/CePO4 with nitrogen and phosphorus co-doped carbon shells for enhanced oxygen reduction reaction catalytic activity, ChemElectroChem, 2018, 5, 793-798. (IF: 3.975) 2. Hongru Wang, Yue Yu, Jiatong Wei, Xiaodan Yu, Gang Chen, Jicheng Ma*, Shuangxi Xing*, Mo0.42C0.58 nanoparticles embedded in nitrogen-doped carbon as electrocatalyst towards oxygen reduction reaction, ChemistrySelect, 2018, 3, 5106-5112. (IF: 1.716) 2017: 1. Yue Yu, Li Gao, Xianchun Liu, Yuanhong Wang, Shuangxi Xing*, Enhancing the catalytic activity of zeolitic imidazolate framework-8-derived N-doped carbon with incorporated CeO2 nanoparticles in the oxygen reduction reaction, Chem. Eur. J., 2017, 23, 10690-10697. (IF: 5.160) 2. Yuhua Feng, Yawen Wang, Xiaohui Song, Shuangxi Xing* and Hongyu Chen*, Depletion sphere: Explaining the number of Ag islands on Au nanoparticles,Chem. Sci., 2017, 8, 430-436. (IF: 9.063) 3. Shuangxi Xing*, Xiaodan Yu, Guibao Wang, Yue Yu, Yuanhong Wang, Yan Xing*, Confined polyaniline derived mesoporous carbon for oxygen reduction reaction, Eur. Polym. J., 2017, 88, 1-8. (IF: 3.741) 4. Shuangxi Xing, Lin Chen, Lei Huang, Tian Wang, Xiaodan Yu, Yuxin Zhang*, Yan Xing*, One-step synthesis of hollow nanostructured aniline oligomers and their derived nitrogen doped carbon, Synth. Met., 2017, 227, 170-176. (IF: 2.526) 5. Liang Zhang, Xianchun Liu*, Yuanhong Wang, Shuangxi Xing*, Controllable silver embedding into polypyrrole, J. Alloy. Compd.,2017, 709, 30, 431-437. (IF: 3.779) 6. Guodong Zhang, Xianchun Liu, Yuanhong Wang, Chengzhan Liu, Shuangxi Xing*, Achieving MnO2 nanosheets through surface redox reaction on nickel nanochains for catalysis and energy storage, Chem. Eur. J., 2017, 23 (23), 5557–5564. (IF: 5.160) 7. Liang Zhang, Xianchun Liu, Yuanhong Wang, Gang Chen, Shuangxi Xing*, Dual role of polyaniline for achieving Ag dendrites and enhancing its oxygen reduction reaction catalytic activity, ChemistrySelect, 2017, 2 (31), 10300-10303. (IF: 1.505)   2016: 1. Li Gao, Linlin Zhang, Shuyan Jia, Xianchun Liu, Yuanhong Wang, Shuangxi Xing*, Facile route to achieve hierarchical hollow MnO2 nanostructures, Electrochim. Acta, 2016, 203, 59-65. (IF: 4.803) 2. Lin Chen, Huibo Wang, Chenzhan Liu, Xianchun Liu*, Shuangxi Xing*, One-pot achieving well-dispersed copper nanoparticles on N-doped carbon films, J. Alloy. Compd., 2016, 656, 622-627. (IF: 3.014) 3. Tian Wang, Qiujian Le, Guodong Zhang, Shijin Zhu, Bo Guan, Junming Zhang, Shuangxi Xing*, Yuxin Zhang*, Facile preparation and sulfidation analysis for activated multiporous carbon@NiCo2S4 nanostructure with enhanced supercapacitive properties,Electrochim. Acta, 2016, 211, 627-635. (IF: 4.803) 2015: 1. Lin Chen, Minling Fang, Chenzhan Liu, Xianchun Liu*, Shuangxi Xing*, Manipulating the nickel shape and catalytic performance: from spheres to chains to urchins, CrystEngComm, 2015, 17, 4343-4348. (IF: 4.034) 2. Dehua Li, Alexis Munyentwali, Guang Wang*, Meiduo Zhang, Shuangxi Xing*, Dyes Pigments, 2015, 117, 92-99. (IF: 3.966) 3. Xiaoguang Qiao, Xianchun Liu, Xiaoting Li, Shuangxi Xing*, Anchoring gold nanoparticles inside polyaniline shells with magnetic cores for the enhancement of catalytic stability, New J. Chem., 2015, 39, 8588-8593. (IF: 3.086) 4. Xiaoting Li, Xianchun Liu, Xiaoguang Qiao, Shuangxi Xing*, Confining the polymerization of aniline to generate yolk–shell polyaniline@SiO2 nanostructures, RSC Adv., 2015, 5, 79172-79177. (IF: 3.84) 2014: 1. Lulu Chen, Lu Li, Tingting Wang, Lingyu Zhang, Shuangxi Xing*, Chungang Wang*, Zhongmin Su, A novel strategy to fabricate multifunctional Fe3O4@C@TiO2 yolk–shell structures as magnetically recyclable photocatalysts, Nanoscale, 2014, 6, 6603-6608. (IF: 7.394) 2. Juan Li, Jian Yan, Chenzhan Liu, Lihong Dong, Hui Lv, Wendong Sun*, Shuangxi Xing*, Manipulation on ZnO heterostructures: from binary ZnO–Ag to ternary ZnO–Ag–polypyrrole, CrystEngComm, 2014, 16, 10943-10948. (IF: 4.034) 3. Sa Lv, Chungang Wang*, Shuangxi Xing*, Hexamethylenetetramine-induced synthesis of hierarchical NiO nanostructures on nickel foam and their electrochemical properties, J. Alloy. Compd., 2014, 603, 190-196. (IF: 2.999) 4. Lei Huang, Xiaodan Yu, Li Gao, Lin Chen, Jiatong Wei, Shuangxi Xing*, Facile synthesis of raspberry-like aniline oligomers with excellent adsorption–desorption properties, New. J. Chem., 2014, 38, 3029-3034. (IF: 3.086) 5. Dehua Li, Meiduo Zhang, Guang Wang*, Shuangxi Xing*, Toward modulation of the naphthopyran photochromism: a miniemulsion copolymerization strategy, New. J. Chem., 2014, 38, 2348-2353. (IF: 3.086) 2013: 1. Jiatong Wei, Guozhong Xing, Li Gao, Hui Suo, Xinping He, Chun Zhao, Sean Li and Shuangxi Xing*, Nickel foam based polypyrrole/Ag composites film: a new route toward stable electrode for supercapacitors, New J. Chem., 2013, 37, 337-341. (IF: 3.086) 2012: 1. Jiao Guo, Jianfang Ma*, Junjie Li, Jin Yang, and Shuangxi Xing*, Unusual 2D → 3D Polycatenane Frameworks Based on 1D → 2D Interdigitated Layers: From Single Crystals to Submicrometer Fibers with Enhanced UV Photocatalytic Degradation Performances, Cryst. Growth Des., 2012, 12, 6074–6082. (IF: 4.891) 2. Li Gao, Sa Lv, Shuangxi Xing*, Facile route to achieve silver@polyaniline nanofibers, Synthetic Met., 2012, 162, 948-952. (IF: 2.252) 3. Sa Lv, Hui Suo, Jinming Wang, Yan Wang, Chun Zhao, Shuangxi Xing*, Facile synthesis of nanostructured Ni(OH)2 on nickel foam and its electrochemical property, Colloid. Surface. A, 2012, 396, 292-298. (IF: 2.752) 4. Xiaobin Xu, Xianchun Liu, Qun Yu, Wei Wang, Shuangxi Xing*, Architecture-adapted raspberry-like gold@polyaniline particles: facile synthesis and catalytic activity, Colloid Polymer Sci., 2012, 290, 1759-1764. (IF: 1.865) 5. Wei Wang, Yujia Pang, Jian Yan, Guibao Wang, Hui Suo, Chun Zhao, Shuangxi Xing*, Facile synthesis of hollow urchin-like gold nanoparticles and their catalytic activity, Gold Bull., 2012, 45, 91-98. (IF: 1.59) 2011: 1. Shuangxi Xing*, Jiating He, Xianchun Liu, Hongyu Chen, A symmetry-adapted shell transformation of core-shell nanoparticles for binary nanoassembly, Chem. Commun., 2011, 47, 12533 - 12535. (IF: 6.834) 2010: 1. Shuangxi Xing, Yuhua Feng, Yee Yan Tay, Tao Chen, Jun Xu, Ming Pan, Jiating He, Huey Hoon Hng, Qingyu Yan, Hongyu Chen*, Reducing the Symmetry of Bimetallic Au@Ag Nanoparticles by Exploiting Eccentric Polymer Shells, J. Am. Chem. Soc., 2010, 132, 9537–9539. (IF: 12.113) 2009: 1. Shuangxi Xing, Li Huey Tan, Miaoxin Yang, Ming Pan, Yunbo Lv, Qinghu Tang, Yanhui Yang and Hongyu Chen*, Highly Controlled Core/Shell Structures: Tunable Conductive Polymer Shells on Gold Nanoparticles and Nanochains, J. Mater. Chem., 2009, 19, 3286-3291. (IF: 7.443) 2. Shuangxi Xing, Li Huey Tan, Tao Chen, Yanhui Yang and Hongyu Chen*, Facile fabrication of triple-layer (Au@Ag)@polypyrrole core-shell and (Au@H2O)@polypyrrole yolk-shell nanostructures, Chem. Commun., 2009, 1653-1654. (IF: 6.834) 2008: 1. Shuangxi Xing*, Hongwei Zheng, Guoku Zhao, Preparation of polyaniline nanofibers via a novel interfacial polymerization method, Synthetic Met., 2008, 158, 59-63. (IF: 2.252)

社会兼职

获奖情况 (数据来源:科学技术处、社会科学处)

  • 2023-12-17 吉林省科学技术奖自然科学奖三等奖
  • 2013-09-01 吉林省自然科学学术成果奖一等奖

教学信息 (数据来源:教务处)

  • 高等物理化学
  • 物理化学选论
  • 物理化学实验(II)
  • 物理化学(I)
  • 物理化学(II)
  • 物理化学(II) 2
  • 专业实习
  • 统计热力学
  • 物理化学(II)
  • 物理化学A-2
  • 毕业论文

科研信息 (数据来源:科学技术处、社会科学处)

  • 项目:
  • 1. 新颖纳米结构金属/碳复合型氧还原电催化剂的构建与性能研究,省、市、自治区科技项目,2021年
  • 2. 复合型氧还原电催化剂的界面设计与性能调控,省、市、自治区科技项目,2020年
  • 3. 双金属纳米粒子/导电聚合物异质结构的构建与性能研究,省、市、自治区科技项目,2015年
  • 4. 多元化超级电容器电极材料的构建,省、市、自治区科技项目,2014年
  • 5. Janus型金属/导电聚合物纳米复合材料的制备与双功能化研究,主管部门科技项目,2013年
  • 6. 金属氧化物-金属-导电聚合物三元纳米异质结构材料的制备与性能研究,国家自然科学基金项目,2011年
  • 7. 胶体法制备Janus纳米粒子及其双功能化研究,省、市、自治区科技项目,2011年
  • 8. 聚苯胺、聚吡咯分散液及其复合物的合成研究,校内自然科学青年基金,2009年
  • 专著:
  • 1. ADVANCED NANOMATERIALS FOR ELECTROCHEMICAL ENERGY CONVERSION AND STORAGE,Elsevier,19-1年
  • 2. 纳米结构导电聚合物研究进展,东北师范大学出版社,01-1年
  • 论文:
  • 1. 3D conductive molecular framework derived MnO2/N, P co-doped carbon as sulfur hosts for high-performance lithium-sulfur batteries,JOURNAL OF ENERGY STORAGE,2023年
  • 2. Three-dimensional polyaniline/cerium oxide composite aerogel with enhanced microwave absorption properties,SYNTHETIC METALS,2023年
  • 3. Hierarchical Rhree-dimensional CoNi LDH-Ni3S2 Supported on Ni Foam as a Stable and Efficient Electrocatalytic Material for Overall Water Splitting,ELECTROANALYSIS,2023年
  • 4. 聚多巴胺包覆银衍生氧还原电催化剂的合成,分子科学学报,2022年
  • 5. Facile Route to Synthesize Cu, S, N-Doped Carbon as Highly Efficient and Durable Electrocatalyst Towards Oxygen Reduction Reaction,CATAL LETT,2022年
  • 6. Interface Engineering of CoO/N-Doped Carbon Nanomaterials as a Bifunctional Electrocatalyst for Rechargeable Zinc-Air Batteries,JOURNAL OF THE ELECTROCHEMICAL SOCIETY,2022年
  • 7. Cu/Co/CoS2 embedded in S,N-doped carbon as highly efficient oxygen reduction and evolution electrocatalyst for rechargeable zinc–air batteries,INORGANIC CHEMISTRY FRONTIERS,2022年
  • 8. Facile route to achieve MoSe2-Ni3Se2 on nickel foam as efficient dual functional electrocatalysts for overall water splitting,FRONTIERS IN ENERGY,2022年
  • 9. 基于镍/氮掺杂碳复合材料的双功能电催化剂合成及电化学性能研究,化学研究与应用 ,2021年
  • 10. Molybdenum and Phosphorous Dual-Doped,Transition-Metal-Based,Free-Standing Electrode for Overall Water Splitting,CHEMELECTROCHEM,2021年
  • 11. 对如何促进学生学好物理化学网络课程的思考,化学教育,2021年
  • 12. A multi-shelled CeO2/Co@N-doped hollow carbon microsphere as a trifunctional electrocatalyst for a rechargeable zinc-air battery and overall water splitting,SUSTAINABLE ENERGY & FUELS,2020年
  • 13. Urea-assisted enhanced electrocatalytic activity of MoS2-Ni3S2 for overall water splitting,INORGANIC CHEMISTRY FRONTIERS,2020年
  • 14. 基于师生问答模式下的物理化学教学效果提升研究,大学(教学与教育),2020年
  • 15. Facile route to achieve Co@Mo2C encapsulated by N-doped carbon as efficient electrocatalyst for overall water splitting in alkaline media,J ELECTROCHEM SOC,2020年
  • 16. Facile route to achieve N, S-codoped carbon as bifunctional electrocatalyst for oxygen reduction and evolution reactions,J ALLOY COMPD,2020年
  • 17. CeO2 encapsulated by iron,sulfur,and nitrogen-doped carbons for enhanced oxygen reduction reaction catalytic activity,CHEMELECTROCHEM,2020年
  • 18. Facile route to achieve bifunctional electrocatalysts for oxygen reduction and evolution reactions derived from CeO2 encapsulated by the zeolitic imidazolate framework-67,INORGANIC CHEMISTRY FRONTIERS,2019年
  • 19. One-pot achievement of MnO2/Fe2O3 nanocomposites for the oxygen reduction reaction with enhanced catalytic activity,NEW J CHEM,2019年
  • 20. Achieving nitrogen-doped carbon/MnO2 nanocomposites for catalyzing the oxygen reduction reaction,DALTON T,2019年
  • 21. A facile route to achieve ultrafine Fe2O3 nanorods anchored on graphene oxide for application in lithium-ion battery,J POWER SOURCES,2019年
  • 22. 物理化学教材中表格数据的深度分析与教学实践-以电解质溶液一章为例,大学化学,2019年
  • 23. Achieving Janus Ag@N-doped carbon for oxygen reduction reaction from eccentric encapsulated Ag@polypyrrole,J ALLOY COMPD,2019年
  • 24. Mo0.42C0.58 Nanoparticles Embedded in Nitrogen-Doped Carbon as Electrocatalyst towards Oxygen Reduction Reaction,CHEMISTRYSELECT,2018年
  • 25. Preparation of Hollow CeO2/CePO4 with Nitrogen and Phosphorus Co-Doped Carbon Shells for Enhanced Oxygen Reduction Reaction Catalytic Activity,CHEMELECTROCHEM,2018年
  • 26. Dual Role of Polyaniline for Achieving Ag Dendrites and Enhancing Its Oxygen Reduction Reaction Catalytic Activity,CHEMISTRYSELECT,2017年
  • 27. Enhancing the catalytic activity of zeolitic imidazolate framework-8-derived N-doped carbon with incorporated CeO2 nanoparticles in the oxygen reduction reaction,CHEM-EUR J,2017年
  • 28. Controllable silver embedding into polypyrrole,J ALLOY COMPD,2017年
  • 29. One-step synthesis of hollow nanostructured aniline oligomers and their derived nitrogen doped carbon,SYNTHETIC MET,2017年
  • 30. Achieving MnO2 Nanosheets through Surface Redox Reaction on Nickel Nanochains for Catalysis and Energy Storage,CHEM-EUR J,2017年
  • 31. Confined polyaniline derived mesoporous carbon for oxygen reduction reaction,EUR POLYM J,2017年
  • 32. Depletion sphere: Explaining the number of Ag islands on Au nanoparticles,CHEMICAL SCIENCE,2017年
  • 33. 从熵的角度解读凝固点降低公式,大学化学,2016年
  • 34. Facile preparation and sulfidation analysis for activated multiporous carbon@NiCo2S4 nanostructure with enhanced supercapacitive properties,ELECTROCHIM ACTA,2016年
  • 35. Design and construction of three-dimensional flower-like CuO hierarchical nanostructures on copper foam for high performance supercapacitor,ELECTROCHIM ACTA,2016年
  • 36. Facile route to achieve hierarchical hollow MnO2 nanostructures,ELECTROCHIM ACTA,2016年
  • 37. Facile Fabrication of Well-Dispersed Pt Nanoparticles in Mesoporous Silica with Large Open Spaces and Their Catalytic Applications,CHEM-EUR J,2016年
  • 38. One-pot achieving well-dispersed copper nanoparticles on N-doped carbon films,J ALLOY COMPD,2016年
  • 39. Anchoring gold nanoparticles inside polyaniline shells with magnetic cores for the enhancement of catalytic stability,NEW J CHEM,2015年
  • 40. Confining the polymerization of aniline to generate yolk-shell polyaniline@SiO2 nanostructures,RSC ADVANCES,2015年
  • 41. Manipulating the nickel shape and catalytic performance: from spheres to chains to urchins,CRYSTENGCOMM,2015年
  • 42. Light and temperature responsive block copolymer assemblies with tunable fluorescence emissions,DYES PIGMENTS,2015年
  • 43. In situ assembly of monodispersed Ag nanoparticles in the channels of ordered mesopolymers as a highly active and reusable hydrogenation catalyst,JOURNAL OF MATERIALS CHEMISTRY A,2015年
  • 44. Manipulation on ZnO heterostructures: from binary ZnO–Ag to ternary ZnO–Ag–polypyrrole,CRYSTENGCOMM,2014年
  • 45. ZIF-8 templated fabrication of rhombic dodecahedron-shaped ZnO@SiO2, ZIF-8@SiO2 yolk–shell and SiO2 hollow nanoparticles,CRYSTENGCOMM,2014年
  • 46. Hexamethylenetetramine-induced synthesis of hierarchical NiO nanostructures on nickel foam and their electrochemical properties,J ALLOY COMPD,2014年
  • 47. Facile synthesis of raspberry-like aniline oligomers with excellent adsorption–desorption properties,NEW J CHEM,2014年
  • 48. A novel strategy to fabricate multifunctional Fe3O4@C@TiO2 yolk–shell structures as magnetically recyclable photocatalysts,NANOSCALE,2014年
  • 49. Toward modulation of the naphthopyran photochromism: a miniemulsioncopolymerization strategy,NEW J CHEM,2014年
  • 50. Designed Fabrication of Unique Eccentric Mesoporous Silica Nanocluster-Based Core–Shell Nanostructures for pH-Responsive Drug Delivery,ACS APPLIED MATERIALS & INTERFACES,2013年
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  • 52. Nickel foam based polypyrrole-Ag composites film: a new route toward stable electrode for supercapacitors,NEW J CHEM,2013年
  • 53. Unusual 2D → 3D polycatenane frameworks based on 1D → 2D interdigitated layers: From single crystals to submicrometer fibers with enhanced UV photocatalytic degradation performances,CRYST GROWTH DES,2012年
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  • 55. Facile route to achieve silver@polyaniline nanofibers,SYNTHETIC MET,2012年
  • 56. Facile synthesis of hollow urchin-like gold nanoparticles and their catalytic activity,GOLD BULL,2012年
  • 57. Measuring the unusually slow ionic diffusion in polyaniline via study of yolk-shell nanostructures,J AM CHEM SOC,2012年
  • 58. Design and fabrication of gas sensing hollow core waveguides in near infrared,OPT COMMUN,2012年
  • 59. One-pot synthesis of nickel oxide–carbon composite microspheres on nickel foam for supercapacitors,J MATER SCI,2012年
  • 60. Facile synthesis of nanostructured Ni(OH)2 on nickel foam and its electrochemical property,COLLOID SURFACE A,2012年
  • 61. A symmetry-adapted shell transformation of core-shell nanoparticles for binary nanoassembly,CHEM COMMUN,2011年
  • 62. Urea-induced direct synthesis of nanostructured α-Ni(OH)2 on nickel foam,CHEM LETT,2011年
  • 63. Triple-Layer (Au@Perylene)@Polyaniline Nanocomposite: Unconventional Growth of Faceted Organic Nanocrystals on Polycrystalline Au,ANGEW CHEM INT EDIT,2011年
  • 64. One-step synthesis of composite vesicles: Direct polymerization and in situ over-oxidation of thiophene,CHEMICAL SCIENCE,2011年
  • 65. Cu2O acting as a robust catalyst in CuAAC reactions: water is the required medium,GREEN CHEM,2011年
  • 66. Mechanistic Investigation into the Spontaneous Linear Assembly of Gold Nanospheres,PHYS CHEM CHEM PHYS,2010年
  • 67. 3D dendritic gold nanostructures: seeded growth of a multi-generation fractal architecture,CHEM COMMUN,2010年
  • 68. Examining the Use of TiO2 to Enhance the NH3 Sensitivity of Polypyrrole Films,J APPL POLYM SCI,2010年
  • 69. Reducing the Symmetry of Bimetallic Au@Ag Nanoparticles by Exploiting Eccentric Polymer Shells,J AM CHEM SOC,2010年
  • 70. Scalable Routes to Janus Au-SiO2 and Ternary Ag-Au-SiO2 Nanoparticles,CHEM MATER,2010年
  • 71. Probing the Kinetics of Ligand Exchange on Colloidal Gold Nanoparticles by Surface-Enhanced Raman Scattering,DALTON T,2010年
  • 72. Fabrication of Polymer Nanocavities with Tailored Openings,ACS NANO,2009年
  • 73. Hydrothermal synthesis of calcium hydroxyapatite nanorods in the presence of PVP,J MATER SCI,2009年
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  • 75. Highly controlled core/shell structures: tunable conductive polymer shells on gold nanoparticles and nanochains,J MATER CHEM,2009年
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  • 77. Synthesis and characterization of PbS/polyaniline core-shell nanocomposites based on octahedral PbS nanocrystals colloid,POLYM COMPOSITE,2008年
  • 78. Preparation of polyaniline nanofibers using the organic solution of aniline as seed,E-POLYMERS,2008年
  • 79. Synthesis of 3D well-packed octahedral PbS nanocrystal arrays,MATER LETT,2008年
  • 80. Preparation of polyaniline nanofibers via a novel interfacial polymerization method,SYNTHETIC MET,2008年
  • 81. Direct synthesis of PbS/polypyrrole core-shell nanocomposites based on octahedral PbS nanocrystals colloid,MATER LETT,2008年
  • 82. Preparation of Polyaniline–Polypyrrole Composite Sub-Micro Fibers via Interfacial Polymerization,POLYM COMPOSITE,2008年
  • 83. Preparation of polyaniline/Fe2O3 composite dispersions in the presence of dodecylbenzene sulfonic acid,E-POLYMERS,2007年
  • 84. Synthesis and characterization of Ag/polypyrrole nanocomposites based on silver nanoparticles colloid,MATER LETT,2007年
  • 85. Examining the use of Fe3O4 nanoparticles to enhance the NH3 sensitivity of polypyrrole films,POLYM BULL,2007年
  • 86. Preparation of highly stable polypyrrole dispersions in the mixed aqueous solution of sodium dodecyl sulfate and polyvinyl pyrrolidone,E-POLYMERS,2007年
  • 87. Preparation and Characterization of Polyaniline-Polypyrrole Composite from Polyaniline Dispersions,J APPL POLYM SCI,2007年
  • 88. Effect of addition of organic solvents on properties of the chemically synthesizes polyaniline in aqueous solutions,E-POLYMERS,2007年
  • 89. Synthesis of octahedral Cu2O microcrystals assisted with mixed cationic/anionic surfactants,MATER LETT,2007年
  • 90. Synthesis and characterization of Ag/polyaniline core-shell nanocomposites based on silver nanoparticles colloid,MATER LETT,2007年
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  • 92. One-step synthesis of polypyrrole-Ag nanofiber composites in dilute mixed CTAB/SDS aqueous solution,MATER LETT,2007年
  • 93. A novel all-plastic diode based upon pure polyaniline material,MICROELECTR J,2007年
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  • 95. Diode-like behavior based on polyaniline and Pt,SOLID STATE ELECTRON,2006年
  • 96. Morphology and gas-sensing behavior of in situ polymerized nanostructured polyaniline films,EUR POLYM J,2006年
  • 97. Morphology and thermostability of polypyrrole prepared from SDBS aqueous solution,POLYM BULL,2006年
  • 98. Preparation of polyaniline dispersions with different assembly structure,J MATER SCI,2006年
  • 99. Morphology and conductivity of polyaniline nanofibers prepared by ‘seeding’ polymerization,POLYMER,2006年
  • 100. Synthesis and characterization of polyaniline in CTAB/hexanol/water reversed micelle,J MATER SCI,2005年
  • 101. Self-organization of spherical PANI/TiO2 nanocomposites in reverse micelles,COLLOID SURFACE A,2004年
  • 102. 聚苯胺纳米粒子的反胶束法合成及自组装,应用化学,2004年
  • 103. Synthesis of PANI/AgCl, PANI/BaSO4 and PANI/TiO2 nanocomposites in CTAB/hexanol/water reverse micelle,MATER LETT,2004年
  • 104. 反胶束体系中合成聚苯胺-无机物复合纳米微粒,ACTA CHIM SINICA,2004年
  • 105. AEOT/异辛烷/水反胶束体系中合成导电聚苯胺,CHEM J CHINESE U,2003年
  • 106. 以反胶束为模板合成导电聚苯胺,东北师大学报(自然科学版),2003年
  • 107. 新型磷酸脂表面活性剂的合成、表征及其反胶束体系对蛋白质的提取,CHEM J CHINESE U,2002年
  • 108. 新型磷酸酯表面活性剂的合成、表征及其反胶束体系对蛋白质的提取,CHEM J CHINESE U,2002年
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