Recent progress of self-supported air electrodes for flexible Zn-air batteries 被引量：1

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摘要 Smart wearable devices are regarded to be the next prevailing technology product after smartphones and smart homes,and thus there has recently been rapid development in flexible electronic energy storage devices.Among them,flexible solid-state zinc-air batteries have received widespread attention because of their high energy density,good safety,and stability.Efficient bifunctional oxygen electrocatalysts are the primary consideration in the development of flexible solid-state zinc-air batteries,and self-supported air cathodes are strong candidates because of their advantages including simplified fabrication process,reduced interfacial resistance,accelerated electron transfer,and good flexibility.This review outlines the research progress in the design and construction of nanoarray bifunctional oxygen electrocatalysts.Starting from the configuration and basic principles of zinc-air batteries and the strategies for the design of bifunctional oxygen electrocatalysts,a detailed discussion of self-supported air cathodes on carbon and metal substrates and their uses in flexible zinc-air batteries will follow.Finally,the challenges and opportunities in the development of flexible zinc-air batteries will be discussed.

作者 Chen Xu Yanli Niu Vonika Ka-Man Au Shuaiqi Gong Xuan Liu Jianying Wang Deli Wu Zuofeng Chen

机构地区 School of Chemical Science and Engineering College of Environmental Science&Engineering Department of Science and Environmental Studies

出处《Journal of Energy Chemistry》 SCIE EI CAS CSCD 2024年第2期110-136,I0004,共28页 能源化学（英文版）

基金 supported by the National Natural Science Foundation of China(22072107,21872105) the Natural Science Foundation of Shanghai(23ZR1464800) the Fundamental Research Funds for the Central Universities the Science&Technology Commission of Shanghai Municipality(19DZ2271500)。

关键词 Bifunctional electrocatalysts Oxygen reduction reaction Oxygen evolution reaction Self-supported air electrodes Flexible zinc-air batteries

分类号 TM911.41 [电气工程—电力电子与电力传动]

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参考文献3

1Yanli Niu,Shuaiqi Gong,Xuan Liu,Chen Xu,Mingze Xu,Shi-Gang Sun,Zuofeng Chen.Engineering iron-group bimetallic nanotubes as efficient bifunctional oxygen electrocatalysts for flexible Zn–air batteries[J].eScience,2022,2(5):546-556. 被引量：8
2Li Li,Linping Hu,Jin Li,Zidong Wei.Enhanced stability of Pt nanoparticle electrocatalysts for fuel cells[J].Nano Research,2015,8(2):418-440. 被引量：15
3Xiaolin Hu,Jichuan Fan,Ronghua Wang,Meng Li,Shikuan Sun,Chaohe Xu,Fusheng Pan.Vacancies and interfaces engineering of core-shell heterostuctured NiCoP/NiO as trifunctional electrocatalysts for overall water splitting and zinc-air batteries[J].Green Energy & Environment,2023,8(2):601-611. 被引量：1

二级参考文献100

1Sharma, S.; Pollet, B. G. Support materials for PEMFC and DMFC electrocatalystsA review. J. Power Sources 2012, 208, 96-119.
2Zhao, Y.; Wang, Y.; Cheng, X.; Dong, L.; Zhang, Y.; Zang, J. Platinum nanoparticles supported on epitaxial TiC/ nanodiamond as an electrocatalyst with enhanced durability for fuel cells. Carbon 2014, 67, 409-416.
3U.S. Departement of Energy. Fuel cell technical team roadmap. 2013. http://energy.gov/sites/prod/files/2014/02/ fS/fctt_roadmap_iune2013.pdf.
4Sun, X.; Li, D.; Ding, Y.; Zhu, W.; Guo, S.; Wang, Z. L.; Sun, S. Core/shell Au/CuPt nanoparticles and their dual electrocatalysis for both reduction and oxidation reactions. J. Am. Chem. Soc. 2014, 136, 5745-5749.
5Su, L.; Jia, W. Z.; Li, C. M.; Lei, Y. Mechanisms for enhanced performance of platinum-based electrocatalysts inproton exchange membrane fuel cells. ChemSusChem 2014, 7, 361-378.
6Marcu, A.; Toth, G.; Pietrasz, P.; Waldecker, J. Cathode catalysts degradation mechanism from liquid electrolyte to membrane electrode assembly. C. R. Chimie. 2014, 17, 752 759.
7Takenaka, S.; Miyamoto, H.; Utsunomiya, Y.; Matsune, H.; Kishida, M. Catalytic activity of highly durable Pt/CNT catalysts covered with hydrophobic silica layers for the oxygen reduction reaction in PEFCs. J. Phys. Chem. C 2014, 118, 774-783.
8Kuo, P. L.; Hsu, C. H.; Wu, H. M.; Hsu, W. S.; Kuo, D. Controllable-nitrogen doped carbon layer surrounding carbon nanotubes as novel carbon support for oxygen reduction reaction. Fuel Cells 2012, 12, 649 655.
9Zhou, X.; Qiao, J.; Yang, L.; Zhang, J. A review of graphene-based nanostructural materials for both catalyst supports and metal-free catalysts in PEM fuel cell oxygen reduction reactions. Adv. Energy Mater. 2014, 4, 1301523.
10Park, J. E.; Jang, Y. J.; Kim, Y. J.; Song, M. S.; Yoon, S.; Kim, D. H.; Kim, S. J. Sulfur-doped graphene as a potential alternative metal-free electrocatalyst and Pt-catalyst suppor- ting material for oxygen reduction reaction. Phys. Chem. Chem. Phys. 2014, 16, 103-109.

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1马英军,马传利,徐金晓,王琳,龚良玉,王杰.Pd和Ru分别修饰Co_(3)O_(4)催化剂的制备及其高效氧催化性能研究[J].稀有金属,2023,47(12):1716-1725. 被引量：2
2Qi Shi,Yingde Wang,Zhongmin Wang,Yongpeng Lei,Bing Wang,Nan Wu,Cheng Han,Song xieJ,Yanzi Gou.Three-dimensional （3D） interconnected networks fabricated via in-situ growth of N-doped graphene/ carbon nanotubes on Co-containing carbon nanofibers for enhanced oxygen reduction[J].Nano Research,2016,9(2):317-328. 被引量：9
3李莉香,张砚秋,孙盼松,安百钢,邢天宇,宋仁峰.氮掺杂活性炭及其载铂催化剂氧还原催化活性[J].新型炭材料,2016,31(3):287-292. 被引量：2
4Huimin Liu,Xinyu Liu,Yumei Li,Yufeng Jia,Yawen Tang,Yu Chen.Hollow PtNi alloy nanospheres with enhanced activity and methanol tolerance for the oxygen reduction reaction[J].Nano Research,2016,9(11):3494-3503. 被引量：2
5赵顺炜,王耀琼,高焕方,许俊强.金属化合物作直接甲醇燃料电池阳极催化剂载体的研究进展[J].化工进展,2017,36(3):965-972. 被引量：5
6Hao Fang,Yuting Chen,Ming Wen,Qingsheng Wu,Quanjing Zhu.SnNi nanoneedles assembled 3D radial nanostructure loaded with SnNiPt nanoparticles： Towards enhanced electrocatalysis performance for methanol oxidation[J].Nano Research,2017,10(11):3929-3940. 被引量：2
7吕路强,沈骏,向路,刘双翼,谢雄,周猛兵.碳基纳米结构作为燃料电池催化剂载体的研究进展[J].材料导报,2017,31(21):9-18. 被引量：1
8丁伟元,赵红,于洪全,刘淑红,刘德宠.静电纺丝技术制备Fe/C催化剂及电化学性能[J].大连交通大学学报,2019,40(5):82-86. 被引量：1
9严婷轩,姚振华,张春梅,胡茂从.氢燃料电池阴极氧还原非金属催化剂研究进展[J].山东化工,2021,50(10):65-69.
10JinKiong Ling,Ria Kunwar,Linlin Li,Shengjie Peng,Izan Izwan Misnon,Mohd Hasbi Ab Rahim,Chun-Chen Yang,Rajan Jose.Self-rechargeable energizers for sustainability[J].eScience,2022,2(4):347-364. 被引量：2

同被引文献10

1Qiaoqiao Zhang,Jingqi Guan.Applications of Atomically Dispersed Oxygen Reduction Catalysts in Fuel Cells and Zinc–Air Batteries[J].Energy & Environmental Materials,2021,4(3):307-335. 被引量：5
2Zhiyan Chen,Qichen Wang,Xiaobin Zhang,Yongpeng Lei,Wei Hu,Yao Luo,Yaobing Wang.N-doped defective carbon with trace Co for efficient rechargeable liquid electrolyte-/all-solid-state Zn-air batteries[J].Science Bulletin,2018,63(9):548-555. 被引量：18
3Jing Zhang,Qiu-an,Huang,Juan Wang,Jing Wang,Jiujun Zhang,Yufeng Zhao.Supported dual-atom catalysts: Preparation, characterization, and potential applications[J].Chinese Journal of Catalysis,2020,41(5):783-798. 被引量：16
4Yiyan Wang,Guoxin Zhang,Mang Ma,Yan Ma,Jiankun Huang,Chen Chen,Ying Zhang,Xiaoming Sun,Zifeng Yan.Ultrasmall NiFe layered double hydroxide strongly coupled on atomically dispersed FeCo-NC nanoflowers as efficient bifunctional catalyst for rechargeable Zn-air battery[J].Science China Materials,2020,63(7):1182-1195. 被引量：12
5Botao Hu,Aijian Huang,Xuejiang Zhang,Zheng Chen,Renyong Tu,Wei Zhu,Zhongbin Zhuang,Chen Chen,Qing Peng,Yadong Li.Atomic Co/Ni dual sites with N/P-coordination as bifunctional oxygen electrocatalyst for rechargeable zinc-air batteries[J].Nano Research,2021,14(10):3482-3488. 被引量：15
6Jun Li,Huaibin Xue,Nengneng Xu,Xiucheng Zhang,Yongxia Wang,Rui He,Haitao Huang,Jinli Qiao.Co/Ni dual-metal embedded in heteroatom doped porous carbon core-shell bifunctional electrocatalyst for rechargeable Zn-air batteries[J].Materials Reports(Energy),2022,2(2):68-74. 被引量：5
7Xiaobo Zheng,Beibei Li,Qishun Wang,Dingsheng Wang,Yadong Li.Emerging low-nuclearity supported metal catalysts with atomic level precision for efficient heterogeneous catalysis[J].Nano Research,2022,15(9):7806-7839. 被引量：31
8Zili Wang,Caiyun Li,Yukun Liu,Yu Wu,Sen Zhang,Chao Deng.Atomically dispersed Fe-Ni dual sites in heteroatom doped carbon tyres for efficient oxygen electrocatalysis in rechargeable Zn-Air battery[J].Journal of Energy Chemistry,2023(8):264-274. 被引量：2
9Shuaifeng Wang,Zhongfang Li,Wenjie Duan,Peng Sun,Jigang Wang,Qiang Liu,Lei Zhang,Yanqiong Zhuang.Conjugated polymerized bimetallic phthalocyanine based electrocatalyst with Fe-N_(4)/Co-N_(4) dual-sites synergistic effect for zinc-air battery[J].Journal of Energy Chemistry,2023(11):41-53. 被引量：1
10Hainan Sun,Xiaomin Xu,Hyunseung Kim,Zongping Shao,WooChul Jung.Advanced electrocatalysts with unusual active sites for electrochemical water splitting[J].InfoMat,2024,6(1):65-82. 被引量：3

引证文献1

1Xiaorong Lin,Gao Chen,Yanping Zhu,Haitao Huang.Advanced dual-atom catalysts for rechargeable zinc-air batteries[J].Energy Reviews,2024,3(3):58-75.

1Bingxin Qi,Xinyue Hong,Ying Jiang,Jing Shi,Mingrui Zhang,Wen Yan,Chao Lai.A Review on Engineering Design for Enhancing Interfacial Contact in Solid-State Lithium–Sulfur Batteries[J].Nano-Micro Letters,2024,16(4):219-252.
2Jiawen Xu,Rong Zhang,Jie Ma,Hanting Zhao,Lianlin Li.In-situ manipulation of wireless link with reinforcement-learningdriven programmable metasurface in indoor environment[J].Journal of Information and Intelligence,2023,1(3):217-227.
3A.Kodam,M.S.Gundi,Y.L.Chiu,I.P.Jones,S.S.Singh,J.Jain.A review of challenges and opportunities in micropillar compression studies in Mg alloys[J].Journal of Magnesium and Alloys,2023,11(11):4043-4053. 被引量：1
4Zongmeng Yang,Shibo Fang,Jing Lu.Low-thermal-budget synthesis of monolayer MoS_(2)[J].Science China Materials,2024,67(1):372-374.
5Oscar Peña-Cáceres,Henry Silva-Marchan,Manuela Albert,Miriam Gil.Recognition of Human Actions through Speech or Voice Using Machine Learning Techniques[J].Computers, Materials & Continua,2023,77(11):1873-1891.
6Jin-Liang Ma,Long-Long Liu,Ren-Hai Zhao,Ding Yuan,Xin Ning.MOF-derived Porous Carbon Nanofiber Assembly as High Efficiency ORR Electrocatalysts for Zinc-air Batteries[J].Chinese Journal of Polymer Science,2023,41(12):1889-1901. 被引量：1
7Xueqing Fu,Gaopeng Li,Xinlu Wang,Jinxian Wang,Wensheng Yu,Xiangting Dong,Dongtao Liu.The etching strategy of zinc anode to enable high performance zinc-ion batteries[J].Journal of Energy Chemistry,2024,88(1):125-143.
8Jiacheng Wang,Liquan Chen,Hong Li,Fan Wu.Anode Interfacial Issues in Solid-State Li Batteries:Mechanistic Understanding and Mitigating Strategies[J].Energy & Environmental Materials,2023,6(4):384-404. 被引量：3
9Expanding Foldable Smartphone Market[J].ChinAfrica,2024,16(3):52-53.
10王利明,Xu Xinyan(译),Hao Siqi(译).加强人权法治保障推动人权事业全面发展[J].China Legal Science,2023,11(S01):83-92.

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2024年第2期

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