杨培霞科研成果

基本信息 科学研究 教育教学 English 发表论文 新建主栏目 基本信息 名称 杨培霞，女。教授/博士生导师, 哈尔滨工业大学化工学院电化学工程系。 先后主持承担了国家自然科学基金面上项目(3项)、黑龙江省自然科学基金项目、中国博士后科学基金项目、博士后研究人员落户黑龙江科研启动资助金、哈尔滨工业大学科研创新基金以及哈尔滨工业大学重大国际科技合作培育计划，参与了多项国家重点研发计划、总装备基础预研、企业课题等。 研究方向 名称 1 锂离子电池负极材料及电解液研究 2 燃料电池及锌空气电池非贵金属催化剂及电池性能研究 3 电子电镀 工作经历 名称 时间 工作经历 2006.11-2008.11 哈工大理学院应用化学系 讲师 2007.08-2010.04 哈工大材料科学与工程博士后流动站 博士后 2008.12-2015.12 哈工大化工学院 副教授/博士生导师 2015.12-至今 哈工大化工与化学学院 教授/博士生导师 教育经历 名称 2000.9-2003.7 黑龙江大学, 无机功能材料专业，硕士 2003.9-2006.11 哈尔滨工业大学，应用化学专业，博士 主要任职 名称 中国电子学会高级会员 中国电子电镀专家委员会委员 《材料保护》杂志编委 研究领域 名称 非贵金属电催化剂 锂离子电池电极材料 电子电镀 团队成员 名称 安茂忠： 教授/博导， 研究方向： 电沉积功能材料，电子电镀，绿色电镀技术 张锦秋：副教授/硕士生导师，研究方向：锂空气电池正极催化材料 ，二氧化碳还原 潘晓娜： 博士生, 研究方向：锂电池聚合物电解质的制备及性能研究。现在美国弗吉尼亚理工大学交流二年。 王 丹： 博士生，研究方向：非贵金属掺杂碳材料及氧还原性能研究 肖力辉：博士生，研究方向：离子液体电沉积CoSe化合物及其电解水性能研究 徐 昊：博士生，研究方向：高载量单原子掺杂碳材料的理论计算与实验研究 刘 磊：工程博士，研究方向：高温闭孔材料的研制与在动力锂离子电池中的应用 王治璞：硕士生，研究方向：锂离子电池高温闭孔隔膜材料的研究 王晗：硕士生，研究方向：电沉积法制备过渡金属磷化物及其电解水性能研究 科研项目 名称 [1] 国家自然科学基金(面上)，电沉积三维自支撑阵列结构催化剂NiCoP-NiCoPOx@NF及其电解水机理研究， 2023.01~2026.12, 主持 [2] 国家自然科学基金(面上)，电化学方法制备氮硫双掺杂三维石墨烯担载纳米CoSe催化剂及其氧还原机理研究 2019.01~2022.12, 主持 [3] 国家自然科学基金(面上)，离子液体复合聚合物电解质的设计合成、导电机理及性能研究， 2013.01~2016.12, 主持 [4] 国家重点研发计划，高强极薄铜箔制造成套技术及关键装备，2021.12-2024.11，参与 [5] 黑龙江省自然科学基金，离子液体脉冲电沉积Pt/石墨烯纳米复合物及催化性能研究，2015.01~2018.12，主持 [6] 中国博士后科学基金，离子液体中SmCo合金的电沉积机理及磁性能研究，2008.01~2009.12，主持 [7] 哈尔滨工业大学科研创新基金，含离子液体的凝胶聚合物电解质的性能及导电机理研究，2010.1-2011.12，主持 [8] 哈尔滨工业大学重大国际科技合作培育计划，氢燃料电池电极新材料的研究，2011.1-2012.12，主持 [9] 博士后研究人员落户黑龙江科研启动资助金项目， 离子液体复合聚合物电解质与碳负极材料界面性质的研究，2011.01~2013.12， 主持 [10]总装备基础预研，特种******研究， 2010.4-2012.4，参与 讲授课程 名称 本科生课程：电镀工艺学、电化学加工技术 硕士生课程：现代电化学表面处理专论 博士生课程：电化学科学与应用技术、电沉积与化学沉积功能材料 招生信息 名称 硕士招生:2-3名/年博士招生:1-2名/年欢迎具有化学、材料等专业背景的同学报考！ English 名称 Peixia Yang School of Chemistry and Chemical Engineering Harbin Institute of Technology 92 West Dazhi Street, Nan Gang District, Harbin, Post Code: 150001 Email: yangpeixia@hit.edu.com Education · 1988 － 1992，B.S., in Environmental Chemistry, Heilongjiang University · 2000 － 2003，M.S., in Inorganic Chemistry, Heilongjiang University · 2003 － 2006，Ph.D., in Applied Chemistry, Harbin Institute of Technology Professional Experience · 2006 － 2008，Lecture, Department of Applied Chemistry, School of Chemical Engineering and Technology, Harbin Institute of Technology · 2007 － 2009，Post-doctor, Center for Post-doctoral Studies in Materials Science and Engineering, Harbin Institute of Technology · 2008 － Present，Associate Professor, Department of Applied Chemistry, School of Chemical Engineering and Technology, Harbin Institute of Technology · 2013 － 2014，Visiting Scholar, Saint-Petersburg State University Institute of Chemistry · 2013 － Present，Doctoral Supervisor, Department of Applied Chemistry, School of Chemical Engineering and Technology, Harbin Institute of Technology · 2016 － Present，Professor, Department of electrochemical engineering, School of Chemistry and Chemical Engineering, Harbin Institute of Technology Research Interests 1. Study on synthesis, electrocatalytic performance and catalytic mechanism of transition metal-nitrogen-doped carbon materials for ORR and OER (1) Based on the dual-nitrogen source route, the zeolite imidazole framework compound (ZIF-8) was employed as the precursor and o-phenanthroline (Phen)/dicyandiamide (DCDA)/urea were used as the nitrogen sources. A series of efficient catalysts have been synthesized after pyrolysis, such as Fe-N-C, Co-N-C, Cu-N-C and FeCo-N-C, which exhibited nice ORR/ OER activity and stability comparable to commercial Pt/C and RuO2 catalysts. M-N-C based liquid and all-solid Zn-air batteries were also assembled, which exhibited the ideal power density and charge/discharge stability (2) A dual-template method was developed to synthesize the hierarchically porous Fe-N-C catalyst, the ZnCl2 and MgO/NaCl as template were employed to construct abundant micropores and mesopores, respectively. The construction of micro/mesoporous structure promoted the exposure of active sites and mass transport of Fe-N-C materials. The effect of the above templates in constructing hierarchically porous morphology was discussed systematically (3) Based on the density functional theory (DFT), the electronic structure of active site, ORR catalytic pathway and corresponding thermodynamic properties of transition metal-nitrogen-carbon (M-N-C) catalysts for ORR were studied by using the Dmol3 code in the Materials Studio software package 2. Metal-free catalyst were prepared based on graphene, and the oxygen reduction reaction (ORR) activity and active sites of the catalysts were explored (1) The natural graphite was used as raw material, and the improved Hummers method were used to prepare graphene oxide (GO). Nitrogen-doped graphene (N-G) was obtained by nitriding at high temperature, which possessed excellent ORR catalytic activity in alkaline medium. The catalytic active sites of N-G were also systematically studied. (2) N-doped porous carbon nanosheets based on graphene were prepared by two-step heat treatment. ZIF-8 crystals with small particle size were grown on the graphene lamellar structure. N-doped carbon nanosheets were prepared by heat treatment, and then the nitrogen content and specific surface area were increased by impregnation and pyrolysis with urea to obtain catalyst. The catalyst showed an excellent ORR activity in alkaline medium and outstanding practical application ability in Zn-air batteries. (3) A three-dimensional porous nitrogen-phosphorus co-doped graphene catalyst (N-P-HGFS) was prepared by hydrothermal and pyrolysis methods. N-P-HGFs have typical lamellar crimped folds, high defect degree, and large specific surface area, resulting in excellent ORR activity in alkaline medium. The assembled Zn-air battery by N-P-HGFs showed a high open circuit potential, high peak power density, and excellent rate performance and stability. (4) Density functional theory (DFT) calculations are performed implemented in DMol3 code of Materials Studio. The generalized gradient approximation with the Perdew-Burke-Ernzerhof (PBE) functional and polarization function (DNP) is employed to describe exchange and correlation effects. The active site configuration, adsorption energy, state density and charge distribution of graphene-based catalyst were calculated. 3. Preparing electrocatalysts via electrodeposition strategy, investigating the overall water electrolysis performances, and adopting Density Functional stimulation to investigate the promotion mechanism of the hydrogen evolution and oxygen evolution activity (1) The CoFeNiP electrocatalyst were fabricated via a novel pulse electrodeposition strategy. Benefit from the modulated electronic states of CoP tuned by Ni and Fe heteroatoms doping with low loading, the as-prepared electrocatalyst exhibits remarkable bifunctional performances of both hydrogen evolution reaction and oxygen evolution reaction, enabling efficient overall water electrolysis for hydrogen production that only requires 1.56 V to reach 10 mA cm-2 (2) A novel gas-templeted electrodeposition strategy was performed to fabricate multi-metallic and heterostructured electrocatalyst labeled as NiCo(OH)x-CoyW, which exhibits outstanding bifunctional electrocatalytic perfermances in alkaline urea-assisted media, with a low voltage of 1.51 V to drive overall electrolysis at 50 mA cm-2. Further DFT analyses demonstrate that W-doping effectively regulate the H immediates adsorption/desorption, thereby promoting the intrinsic activity. (3) A bottom-up strategy was performed, with the former electrochemical anodic oxidation followed by phosphating and secondary electrodeposition, to prepare novel heterostructured electrocatalysts of Cu3P-NiCo(OH)x and Cu3P-NiFe(OH)x, respectively. Further analyses unveil that bimetallic hydroxides coupling results in a fully exposed active sites, thereby promoting the overall water electrolysis performances, which requires 1.58 V to reach a current density of 10 mAcm-2 for hydrogen production as well as long-term stability. 4. Ag and CdS nanofilms were prepared between the surfactants/electrolyte interface via electrodeposition. The structure, composition and comprehensive properties of the as-prepared Ag and CdS nanofilms were systematically characterized, and the corresponding deposition mechanism was studied. The plural dielectron and plural refractive constants under different wavelengths were measured by ellipse polarization. 5. CuInGaSe thin films for solar-cells were prepared via electrodeposition in Ionic liquid polymer electrolyte. The electrodeposition processes and the co-deposition mechanism of CuInGaSe in Ionic liquid polymer electrolyte were investigated, and the photoelectric conversion efficiency of the as-prepared films was further measured. 6. Nine type of binary ionic liquid electrolyte combinations were prepared by filtering and mixing buthy-3-methylimidazofium tetrafluoroborate, 1-buthy-3-ethylimidazolium bis (trifluoro methanesulfonimide), 1-methyl-3-ethylimidazolium bis(trifluoromethanesulfonimide) with lithium perchlorate, lithium hexafluorophosphate, lithium bis (trifluoro methanesulfonimide) respectively. Meanwhile, the electrochemical compatibilities with LiCoO2, LiFePO4, Li4Ti5O12 and graphite (MAGD) were also evaluated. 7. Ionic liquid gel polymer electrolyte (ILGPE) was prepared via solution casting technology with P(VdF-HFP), ionic liquid, lithium salt as the main components, and small molecular ethylene carbonate (EC)-propylene carbonate(PC) as additives. The electronic conduction behavior and the compatibility with LiFePO4, Li4Ti5O12 were also studied. 8. The environmentally electrodeposition technologies have been developed to prepare cyanide-free electroplating including gold, silver, copper, nano-zinc, high corrosion-resistant zinc-nickel alloys, and functional coating that can replace hard chrome, respectively. Projects supervised or involved [1] Preparation and Oxygen Reduction Mechanism of Nano Co1-xSe Catalyst Supported on Nitrogen and Sulfur Dual-Doped Three-Dimensional Graphene by Electrodeposition, NO. 21878061, National Natural Science Foundation of China (General Program), 2019.01-2022.12 (supervisor). [2] A study of the catalytic performance of Pt/graphene nano-composites prepared by pulsed-electrodeposition from ionic liquids, NO. B2015004, Natural Science Foundation of Heilongjiang Province of China (General Program), 2015.07-2018.07 (supervisor). [3] Synthesis, electrical conduction mechanisms, and performance study of composite polymer electrolytes containing ionic liquid, NO. 21276057, National Natural Science Foundation of China (General Program), 2013.01-2016.12 (supervisor). [4] A study of the interface properties between carbon anode materials and composite polymer electrolyte containing ionic liquid, NO. LBH-Q10099, the project supported by Scientific Research Starting Foundation for post-doctor researchers who settle down in HeiLongjiang province, 2011.01-2013.12 (supervisor). [5] A study of the new electrode materials for hydrogen cells, NO. HIT. ICRST.2010005, Incubation programme for international scientific and technological cooperation by Harbin Institute of Technology, 2011.1-2012.12 (supervisor). [6] A study of the performance and electrical conduction mechanisms of gel polymer electrolytes containing ionic liquid, NO. HIT. NSRIF. 2009121, Scientific research innovation fund of Harbin Institute of Technology, 2010.1-2011.12, (supervisor). [7] Synthesis and performance study of gel polymer electrolytes containing ionic liquid, NO. B2007-05, Natural Science Foundation of Heilongjiang Province of China, 2008.01~2010.12, (supervisor). [8] A study of electrodeposition mechanism and its magnetic property of SmCo alloy from ionic liquids, NO. 20080440865, China Postdoctoral Science Foundation, 2008.01-2009.12, (supervisor). [9] A study of the formation mechanism, structure, and magneto-optical property of TbFeCo alloy electrodeposited from ionic liquids, NO. 50171033, National Natural Science Foundation of China, 2008.01-2010.12, the second supervisor, in charge of the performance of the alloy deposits. [10] A fundamental study of the CIGS thin film solar cell with high photoelectric conversion efficiency, NO. ZD201107, Natural Science Foundation of Heilongjiang Province of China (Key Program), 2012.01-2014.12, the second supervisor, in charge of preparing thin film from ionic liquids. Publications [1] Hao Xu, Dan Wang, Peixia Yang* , Lei Du*, Xiangyu Lu, Ruopeng Li, Lilai Liu, Jinqiu Zhang, Maozhong An. A hierarchically porous Fe-N-C synthesized by dual melt-salt-mediated template as advanced electrocatalyst for efficient oxygen reduction in zinc-air battery. Applied Catalysis B: Environmental, 2022, 305:121040 [2] Yun Li, Ruopeng Li, Dan Wang, Hao Xu, Fan Meng, Derui Dong, Jie Jiang, Jinqiu Zhang, Maozhong An, Peixia Yang*. A review: Target-oriented transition metal phosphide design and synthesis for water splitting. International Journal of Hydrogen Energy, 2021,46(7): 5131-5149 [3] Dan Wang, Peixia Yang*, Hao Xu, Jingyuan Ma*, Lu Du*, Guoxu Zhang, Ruopeng Li, Zheng Jiang, Yun Li, Jinqiu Zhang, Maozhong An. The dual-nitrogen-source strategy to modulate a bifunctional hybrid Co/Co-N-C catalyst in the reversible air cathode for Zn-air batteries. Journal of power sources, 2020. 10.1016/j.jpowsour.2020.229339 [4] Hao Xu, Dan Wang, Peixia Yang*, Anmin Liu*, Ruopeng Li, Yun Li, Lihui Xiao, Xuefeng Ren, Jinqiu Zhang, Maozhong An, Atomically dispersed M–N–C catalysts for the oxygen reduction reaction, Journal of Materials Chemistry A, 2020, 8: 23187-23201 [5] Dan Wang, Xiaona Pan, Peixia Yang*, Ruopeng Li, Hao Xu, Yun Li, Fan Meng, Jinqiu Zhang, Maozhong An. Transition metal and nitrogen co-doped carbon-based electrocatalysts for oxygen reduction reaction: From active site insights to the rational design of precursors and structures. ChemSusChem, 2020. doi.org/10.1002/cssc.202002137 [6] Hao Xu, Dan Wang, Peixia Yang*, Anmin Liu*, Ruopeng Li, Yun Li, Lihui Xiao, Jinqiu Zhang, Maozhong An, A theoretical study of atomically dispersed MN4/C (M = Fe or Mn) as a high-activity catalyst for the oxygen reduction reaction, Physical Chemistry Chemical Physics, 2020, 22: 28297-28303 [7] Dan Wang, Lihui Xiao, Peixia Yang*, Zhengrui Xu, Xiangyu Lu, Lei Du, Oleg Levin, Liping Ge, Xiaona Pan, Jinqiu Zhang, Maozhong An, Dual-nitrogen-source engineered Fe–Nx moieties as a booster for oxygen electroreduction, Journal of Materials Chemistry A, 2019, 7: 11007-11015 [8] Liping Ge, Dan Wang, Peixia Yang*, Hao Xu, Lihui Xiao, Guo-Xu Zhang*,Xiangyu Lu, Zhenzhen Duan, Fan Meng, Jinqiu Zhang, Maozhong An, Graphite N-C-P dominated three-dimensional nitrogen and phosphorus co-doped holey graphene foams as high-efficiency electrocatalysts for Zn–air batteries, Nanoscale, 2019,11: 17010-17017 [9] Pan Xiaona, Liu Tianyi, Kautz David J.,Mu Linqin, Tian Chixia, Long Timothy E., Yang Peixia*, Lin Feng*，High-performance N-methyl-N- propylpi peridinium bis (trifluoromethanesulfonyl) imide/poly (vinylidene fluoride- hexafluoropropylene) gel polymer electrolytes for lithium metal batteries，Journal of Power Sources, 2018, 403: 127-136 [10] Lu Xiangyu#, Du Lei#, Wang Dan, Yang Peixia*, Liu Lilai，Jinqiu Zhang, Maozhong An, Oleg Levin, Jinpeng Wang, Liping Ge. Highly dispersed Cu-NX moieties embedded in graphene: a promising electrocatalyst towards the oxygen reduction reaction, ChemElectroChem, 2018,5(21):3323-3329 [11] Lu Xiangyu, Wang Dan, Ge Liping, Xiao Lihui, Zhang Haiyan, Liu Lilai, Zhang Jinqiu, An Maozhong, Yang Peixia*. Enriched graphitic N in nitrogen-doped graphene as a superior metal-free electrocatalyst for oxygen reduction reaction, New Journal of Chemistry, 2018, 42:19665-19670 [12] Pan Xiaona, Zhang Haiyan, Wen Xiaoyu, Zhang Jinqiu, An Maozhong, Yang Peixia*, Template-Free Electrochemical Preparation of Hexagonal CuSn Prism-Structural Electrode for Lithium-Ion Batteries，Journal of Nanomaterials, 2018, Article ID 1507985, 5 pages [13] Wang Dan, Liu Lilai, Li Mingxian, Pan Xiaona, ZhaoYanhong, Zhang Jinqiu, An Maozhong, Yang Peixia*, Preparation of Platinum Nanoparticles via Electrochemical Method in N, N-diethyl-N-methyl-N-(2-methoxyethyl) ammonium tetrafluoroborate Ionic Liquid, Chinese Journal of Inorganic Chemistry, 2018, 34(2): 409-414 [14] Nikita Kuznetsov, Peixia Yang, Georgy Gorislov, Yuri Zhukov, Vladimir Bocharov Valery Malev, Oleg Levin*, Electrochemical transformations of polymers formed from nickel (II) complexes with salen-type ligands in aqueous alkaline electrolytes, Electrochimica Acta, 2018, 271:190-20 [15] Wen Xiaoyu, Pan Xiaona, Wu Linbin, Li Ruinan, Wang Dan, Zhang Jinqiu, Yang Peixia*，Preparation of textural lamellar tin deposits via electrodeposition，Applied Physics A, 2017, 123(6): 423 [16] Pan Xiaona, Hou Jun, Liu Lei, Yang Peixia*, Zhang Jinqiu, An Maozhong,，A piperidinium-based ester-functionalized ionic liquid as electrolytes in Li/LiFePO4 batteries, Ionics, 2017, 23(11): 3151-3161 [17] Pei-xia Yang*, Jie Zhang, Lei Liu, Mao-zhong An, Electroless Deposition of Nickel Nanowire and Nanotube Arrays as Supports for Pt-Pd Catalyst for Ethanol Electrooxidation, Chinese journal of chemical physics, 2015, 28(2):206-208 [18] PeiXia Yang*, Lei Liu, LiBo Li, et al. Gel polymer electrolyte based on polyvinylidenefluoride-co-hexafluoropropylene and ionic liquid for lithium ion battery. Electrochimica Acta, 2014, 115: 454-460 [19] Peixia Yang, Yanbiao Zhao, Caina Su, Kaijian Yang; Bo Yan; Maozhong An*, Electrodeposition of Cu-Li alloy from room temperature ionic liquid 1-butyl-3-methylimidazolium tetrafluoroborate. Electrochimica Acta, 2013, 88:203-207 [20] Lei Liu, Peixia Yang？, Libo Li, et al. Application of bis (trifluoromethanesulfonyl) imide lithium-N-methyl-N-butylpiperidinium-bis(trifluorome thanesul fonyl) imide-poly(vinylidene difluoride-co-hexafluoropropylene) ionic liquid gel polymer electrolytes in Li/LiFePO4 batteries at different temperatures. Electrochimica Acta, 2012, 85: 49-56 Authorized Patents [1] Peixia Yang, Maozhong An, Caina Su, et al. a method of electrodepositing metal lanthanum from ionic liquids. Patent number: ZL201110435737. [2] Peixia Yang, Maozhong An, Xuefeng Ren, et al. a method of electrodepositing Ni-Co-C alloy as the alternate of hard chrome electrodeposit. Patent number: ZL 201110338085. [3] Peixia Yang, Maozhong An. a method of electrodepositing metal cobalt from ionic liquids, Patent number: ZL 200610010063.0. [4] Peixia Yang, Maozhong An. a method of preparing highly ordered porous anodic aluminum oxide templates with mixed acid electrolytes. Patent number: ZL200510010566.3. [5] Maozhong An, Caina Su, Peixia Yang, et al. a method of Patent number: preparing Tb-Co alloy by using the technology of ionic liquids electrodeposition. Patent number: ZL 2009 1 0071687.7. [6] Maozhong An, Caina Su, Peixia Yang, et al. a method of preparing TbFeCo alloy thin films by using the technology of ionic liquids pulsed-electrodeposition. Patent number: ZL 2009 1 0071688.1 [7] Maozhong An, Anmin Liu, Peixia Yang, et al. Cyanide-free silver electroplating bath and its preparation as well as the electroplating method. Patent number: ZL 201110088379.2. [8] Jinqiu Zhang, Maozhong An, Peixia Yang, et al. a method of preparing chromate-free passivation solutions and its use in the passivation of zinc and zinc alloy electrodeposits. Patent number: ZL200910312379.9. 名称 [1] Lu Xiangyu, Xu Hao, Yang Peixia*, Xiao Lihui, Li Yaqiang, Ma Jingyuan*, Li Ruopeng, Liu Lilai, Liu Anmin, Veniamin Kondratiev, Oleg Levin, Zhang Jinqiu, An Maozhong. Zinc-assisted MgO template synthesis of porous carbon-supported Fe-Nx sites for efficient oxygen reduction reaction catalysis in Zn-air batteries, Applied Catalysis B: Environmental, 2022, 313: 121454 （IF=23.9） [2] Hao Xu, Dan Wang, Peixia Yang*, Lei Du*, Xiangyu Lu, Ruopeng Li, Lilai Liu, Jinqiu Zhang, Maozhong An. A hierarchically porous Fe-N-C synthesized by dual melt-salt-mediated template as advanced electrocatalyst for efficient oxygen reduction in zinc-air battery. Applied Catalysis B: Environmental, 2022, 305:121040（IF=23.9） [3] X. Pan, P. Yang, Y. Guo, K. Zhao, B. Xi, F. Lin*, S. Xiong*. Electrochemical and Nanomechanical Properties of TiO2 Ceramic Filler Li-Ion Composite Gel Polymer Electrolytes for Li Metal Batteries. Advanced Materials Interfaces 2021, 8, 2100669. (IF=6.1) [4] Dan Wang, Hao Xu, Peixia Yang*, Xiangyu Lu, Jingyuan Ma*, Ruopeng Li, Lihui Xiao, Jinqiu Zhang, Maozhong An. Fe-N4 and Co-N4 dual sites for boosting oxygen electroreduction in Zn-air batteries[J]. Journal of Materials Chemistry A, 2021, 9(23):13678-13687 (IF=14.2) [5] Xiangyu Lu, Liping Ge, Peixia Yang*, Oleg Levin, Veniamin Kondratiev, Zhenshen Qu, Lilai Liu, Jinqiu Zhang, Maozhong An. N-doped carbon nanosheets with ultra-high specific surface area for boosting oxygen reduction reaction in Zn-air batteries. Applied Surface Science 2021, 562: 150114. (IF=7.2) [6] Wang Dan, Xu Hao, Yang Peixia*, Xiao Lihui, Du Lei*, Lu Xiangyu, Li Ruopeng, Zhang Jinqiu, An Maozhong. A dual-template strategy to engineer hierarchically porous Fe-N-C electrocatalyst for high-performance cathode of Zn-air batteries[J]. Journal of Materials Chemistry A. 2021, 9, 9761-9770. (IF=14.2) [7] Dan Wang, Peixia Yang*, Hao Xu, Jingyuan Ma*, Lei Du*, Guoxu Zhang, Ruopeng Li, Zheng Jiang, Yun Li, Jinqiu Zhang, Maozhong An. The dual-nitrogen-source strategy to modulate a bifunctional hybrid Co/Co-N-C catalyst in the reversible air cathode for Zn-air batteries. Journal of power sources, 2021, 485: 229339 (IF=9.6) [8] Hao Xu, Dan Wang, Peixia Yang*, Anmin Liu*, Ruopeng Li, Yun Li, Lihui Xiao, Xuefeng Ren, Jinqiu Zhang, Maozhong An, Atomically dispersed M–N–C catalysts for the oxygen reduction reaction, Journal of Materials Chemistry A, 2020, 8: 23187-23201 (IF=14.2) [9] Xiaona Pan, Lei Liu, Peixia Yang*, Jinqiu Zhang, Maozhong An. Effect of interface wetting on the performance of gel polymer electrolytes-based solid-state lithium metal batteries. Solid State Ionics, 2020, 357: 115466. (IF=3.6) [10] Dan Wang, Lihui Xiao, Peixia Yang*, Zhengrui Xu, Xiangyu Lu, Lei Du*, Oleg Levin, Liping Ge, Xiaona Pan, Jinqiu Zhang, Maozhong An, Dual-nitrogen-source engineered Fe–Nx moieties as a booster for oxygen electroreduction, Journal of Materials Chemistry A, 2019, 7: 11007-11015 (IF=14.2) [11] Pan Xiaona, Liu Tianyi, Kautz David J.,Mu Linqin, Tian Chixia, Long Timothy E., Yang Peixia*, Lin Feng*，High-performance N-methyl-N- propylpi peridinium bis (trifluoromethanesulfonyl) imide/poly (vinylidene fluoride- hexafluoropropylene) gel polymer electrolytes for lithium metal batteries，Journal of Power Sources, 2018, 403: 127-136 (IF=9.6)