Supported dual-atom catalysts: Preparation, characterization, and potential applications 被引量：18

双原子催化剂:制备、表征和应用

在线阅读下载PDF

导出

摘要 Developing sustainable and clean electrochemical energy conversion technologies is a crucial step in addressing the challenges of energy shortage and environmental pollution. Exploring and developing new electrocatalysts with excellent performance and low cost will facilitate the commercial use of these energy conversion technologies. Recently, dual-atom catalysts(DACs) have attracted considerable research interest since they exhibit higher metal atom loading and more flexible active sites compared to single-atom catalysts(SACs). In this paper, the latest preparation methods and characterization techniques of DACs are systematically reviewed. The advantages of homonuclear and heteronuclear DACs and the catalytic mechanism and identification technologies between the two DACs are highlighted. The current applications of DACs in the field of electrocatalysis are summarized. The development opportunities and challenges of DACs in the future are prospected. The ultimate goal is to provide new ideas for the preparation of new catalysts with excellent properties by customizing diatomic catalysts for electrochemical applications. 发展可持续和清洁的电化学能源转化技术是应对能源短缺和环境污染挑战的关键一步,燃料电池、电解电池和金属空气电池作为清洁能源储存和转换装置目前得到广泛应用推广,这些装置依靠电催化反应以及电极材料上发生的电荷转移过程来转换电能和化学能.而电催化剂是该类装置电极材料的核心部件,电催化反应的热力学和动力学过程与电催化剂的物理性质和化学状态密切相关.因此探索和开发性能优良、成本低廉的新型电催化剂,将进一步促进这些能源转化技术的商业化应用.单原子催化剂(SACs)以其暴露的活性位点、高选择性和最大限度地原子利用率而受到人们的广泛关注.然而,随着单原子表面自由能的增加,粒子在制备和催化过程中的聚集,催化活性位点的降低和催化剂负荷的相对较低,严重制约了SACs的发展和应用.考虑到SACs的缺点,为了进一步增加单原子活性位点的数量和负载,双原子催化剂(DACs)作为SACs家族成员的扩展近年来逐渐兴起,且两种金属原子(同核/异核)在DACs中的协同作用显著提高了催化剂的催化活性.本文基于当前最新的研究工作对比了同核/异核DACs的不同优势,列举了一系列包括原子层沉积法、湿化学吸附法以及高温热处理法等方法用于制备性能优异的DACs,其中高温热处理法因应用广泛被重点强调.同时,本文也对DACs的表征和识别手段进行了重点概括,包含XANES, EXAFS, IR, DFT等;详细概括和对比了当前DACs在电化学方面的主要应用,如氧还原反应(ORR)和二氧化碳还原反应.目前, DACs作为一个新兴的研究领域,由于其金属原子负载量高、活性位点比SACs更为灵活,已经在电催化领域取得了快速的发展.相对于同核DACs,原则上不同的两个金属原子会组成更多的异核DACs,因此,对于性能优异的异核DACs还有更多的可能性值得深入探索.可以预见, DACs的发展将弥补SACs的不足,在电化学能源的转换和储存方面发挥全面的优势;借助于异核DACs中不同的两个金属原子的多样性,探索以过渡金属为主的DACs,将会为节约贵金属资源及环境保护带来巨大贡献,进一步设计和优化DACs,有利于燃料电池和金属-空气电池创造出更大的经济效益和社会效益.因此,我们相信DACs的发展将成为材料研究的一个新前沿,并为合成更多的高效应用催化剂开辟一条新的途径.

作者 Jing Zhang Qiu-an Huang Juan Wang Jing Wang Jiujun Zhang Yufeng Zhao 张晶;黄秋安;王娟;王静;张久俊;赵玉峰(上海大学可持续能源研究院/理学院,上海200444;西安建筑科技大学机电工程学院,陕西省纳米材料与技术重点实验室,陕西西安710055;燕山大学应用化学重点实验室,河北秦皇岛066004)

机构地区 Institute for Sustainable Energy/College of Sciences Shanxi Key Laboratory of Nanomaterials and Nanotechnology Key Laboratory of Applied Chemistry

出处《Chinese Journal of Catalysis》 SCIE EI CAS CSCD 北大核心 2020年第5期783-798,共16页 催化学报（英文）

基金国家自然科学基金(51774251) 河北杰出青年科学基金(B2017203313) 河北省百名创新人才经费(SLRC2017057) 特种电源国家重点实验室开放基金(SKL-ACPS-C-11) 河北省人才工程培养经费(A201802001).

关键词 Dual–atoms catalyst HOMONUCLEAR HETERONUCLEAR ELECTROCATALYST Energy conversion and storage device 双原子催化剂同核异核电化学能源转换和储存

分类号 TM911.4 [电气工程—电力电子与电力传动] O643.36 [理学—物理化学]

作者简介通讯联系人:王娟,电子信箱:juanwang168@gmail.com;通讯联系人:赵玉峰,电子信箱:yufengzhao@shu.edu.cn。

引文网络
相关文献

同被引文献149

1Hong-Yu Gong,Xiu Liang,Guan-Liang Sun,Dong-Wei Li,Xiang-Jun Zheng,Huan Shi,Kai Zeng,Guan-Chen Xu,Yong Li,Rui-Zhi Yang,Chang-Zhou Yuan.Insight into role of Ni/Fe existing forms in reversible oxygen catalysis based on Ni-Fe single-atom/nanoparticles and N-doped carbon[J].Rare Metals,2022,41(12):4034-4040. 被引量：8
2Qiaoqiao 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
3HongyanShang,ChenguangLiu,FeiWei.FT-IR Study of Carbon Nanotube Supported Co-Mo Catalysts[J].Journal of Natural Gas Chemistry,2004,13(2):95-100. 被引量：1
4李斗星.原子分辨率的原子序数衬度成像及应用[J].电子显微学报,2005,24(4):245-245. 被引量：3
5曾成华.负载型金属催化剂的研究进展[J].攀枝花学院学报,2006,23(2):110-114. 被引量：7
6吕倩,孟明,查宇清.高热稳定性纳米Au/TiO_2催化剂的制备与表征[J].催化学报,2006,27(12):1111-1116. 被引量：15
7马礼敦.X射线吸收光谱及发展[J].上海计量测试,2007,34(6):2-11. 被引量：13
8张齐,戴伟,穆玮,于海波.原位红外光谱法研究Pd-Ag/Al_2O_3和Pd/Al_2O_3乙炔加氢催化剂[J].化工学报,2011,62(1):71-77. 被引量：13
9Chiara Genovese,Claudio Ampelli,Siglinda Perathoner,Gabriele Centi.Electrocatalytic conversion of CO_2 to liquid fuels using nanocarbon-based electrodes[J].Journal of Energy Chemistry,2013,22(2):202-213. 被引量：6
10Konglin Wu,Xin Chen,Shoujie Liu,Yuan Pan,Weng-Chon Cheong,Wei Zhu,Xing Cao,Rongan Shen,Wenxing Chen,Jun LUO,Wensheng Yan,Lirong Zheng,Zheng Chen,Dingsheng Wang,Qing Peng,Chen Chen,Yadong Li.Porphyrin-like Fe-N4 sites with sulfur adjustment on hierarchical porous carbon for different rate-determining steps in oxygen reduction reaction[J].Nano Research,2018,11(12):6260-6269. 被引量：21

引证文献18

1左国防,王鹏,廖天录.N掺杂碳基单原子催化剂在电化学生物传感领域的研究与应用[J].功能材料与器件学报,2022(4):301-307. 被引量：1
2赵梦源,吕晓猛,张皓哲,贾瑛.低Pt纳米电催化剂的水热合成法制备及性能研究[J].火箭军工程大学学报,2021(1):79-82. 被引量：1
3张晶,宋良浩,赵晨妃,殷秀平,赵玉峰.钴,氮共掺杂多孔炭用于高性能氧还原电催化剂[J].新型炭材料,2021,36(1):209-218. 被引量：7
4Zhao Lei,Yangyang Tan,Zeyi Zhang,Wei Wu,Niancai Cheng,Runzhe Chen,Shichun Mu,Xueliang Sun.Defects enriched hollow porous Co-N-doped carbons embedded with ultrafine CoFe/Co nanoparticles as bifunctional oxygen electrocatalyst for rechargeable flexible solid zinc-air batteries[J].Nano Research,2021,14(3):868-878. 被引量：17
5白羽,满毅,柳颖,杜雪丽.负载型金属催化剂原子级表征及研究进展[J].分析仪器,2021(2):42-49.
6徐先燕,杨彪,吴俊朗,赵存元.双金属掺杂石墨烯的析氧反应性能[J].韶关学院学报,2021,42(9):36-41. 被引量：1
7于芹芹,戴友芝,张莉,林艺佳,伍倩,张柱.非贵金属单原子催化剂的研究进展[J].化工环保,2022,42(2):143-147. 被引量：3
8Ligang Ma,Junlin Li,Zhiwei Zhang,Hao Yang,Xueqin Mu,Xiangyao Gu,Huihui Jin,Ding Chen,Senlin Yan,Suli Liu,Shichun Mu.Atomically dispersed dual Fe centers on nitrogen-doped bamboo-like carbon nanotubes for efficient oxygen reduction[J].Nano Research,2022,15(3):1966-1972. 被引量：3
9Xiaobo 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：35
10Riming Hu,Yanan Yu,Yongcheng Li,Yiran Wang,Jiaxiang Shang,Yong Nie,Xuchuan Jiang.Rational design of bimetallic atoms supported on C3N monolayer to break the linear relations for efficient electrochemical nitrogen reduction[J].Nano Research,2022,15(9):8656-8664.

二级引证文献69

1李平,王焕磊.炭负载铁系元素催化剂在氧还原反应中的应用研究进展[J].新型炭材料,2021,36(4):665-682. 被引量：3
2王信,黄润青,牛树章,徐磊,张启程,Abbas Amini,程春.石墨烯基材料在高性能锂金属电池中的研究进展[J].新型炭材料,2021,36(4):711-728. 被引量：8
3Shenlong Zhao,Detao Zhang,Shuai Jiang,Yanglansen Cui,Haijing Li,Juncai Dong,Zhirun Xie,Da-Wei Wang,Rose Amal,Zhenhai Xia,Liming Dai.Carbon-supported layered double hydroxide nanodots for efficient oxygen evolution: Active site identification and activity enhancement[J].Nano Research,2021,14(9):3329-3336. 被引量：2
4邓晓华,江柱,陈超,党岱.沸石咪唑基金属有机框架及其衍生材料用作锌-空气电池高效阴极催化剂的最新进展[J].储能科学与技术,2022,11(3):964-981. 被引量：1
5Benji Zhou,Yanyan Liu,Xianli Wu,Huan Liu,Tao Liu,Yi Wang,Sehrish Mehdi,Jianchun Jiang,Baojun Li.Wood-derived integrated air electrode with Co-N sites for rechargeable zinc-air batteries[J].Nano Research,2022,15(2):1415-1423. 被引量：3
6XU ZhuYing,YAN Lei,SHEN JunLing,YANG XiaoJing,NING JiQiang,ZHONG YiJun,HU Yong.Hierarchical mesoporous S,N-codoped carbon nanostructures composed of Co/Co-Cu-S/carbon nanoplate arrays on carbon nanofibers as a self-supported air cathode for long-lasting rechargeable Zn-air batteries[J].Science China(Technological Sciences),2022,65(3):693-703. 被引量：2
7Hang Liu,Lenus Syama,Like Zhang,Carmen Lee,Chuntai Liu,Zhengfei Dai,Qingyu Yan.High-entropy alloys and compounds for electrocatalytic energy conversion applications[J].SusMat,2021,1(4):482-505. 被引量：4
8Miaosen Yang,Yifan Liu,Jiaqiang Sun,Shusheng Zhang,Xijun Liu,Jun Luo.Integration of partially phosphatized bimetal centers into trifunctional catalyst for high-performance hydrogen production and flexible Zn-air battery[J].Science China Materials,2022,65(5):1176-1186. 被引量：5
9Jun Chen,Liandong Li,Liu Yang,Chang Chen,Shitao Wang,Yan Huang,Dapeng Cao.A dual metal-organic framework strategy for synthesis of FeCo@NC bifunctional oxygen catalysts for clean energy application[J].Chinese Journal of Chemical Engineering,2022,35(3):161-168. 被引量：3
10Hanzhen Zheng,Fei Ma,Hongcen Yang,Xiaogang Wu,Rui Wang,Dali Jia,Zhixia Wang,Niandi Lu,Fen Ran,Shanglong Peng.Mn,N co-doped Co nanoparticles/porous carbon as air cathode for highly efficient rechargeable Zn-air batteries Hide Author's Information[J].Nano Research,2022,15(3):1942-1948. 被引量：3

1吴乐.“科学精神与社会责任”理念在工艺流程中的落脚点[J].中学生数理化（高考理化）,2020,0(3):44-44.
2赵海峰.电力系统安全稳定综合防御体系框架[J].门窗,2019(22):298-298. 被引量：1
3耿哲,黄艳,林慧敏.基于新旧能源转换的农村煤改气问题研究——以烟台市莱山区为例[J].科技经济导刊,2020,0(1):90-90.
4赵勇宁.新形势下油田消防安全环保管理的新措施[J].消防界（电子版）,2020,6(4):54-54. 被引量：6
5普麟.热能与动力工程中的节能措施[J].节能与环保,2020(1):34-35. 被引量：2
6李保荣(摘译).一次性塑料转变为液态烃[J].石油石化绿色低碳,2020,5(1):25-25.
7Shi-yang Zhang,Feng Xie,Feng-dong Jia,Xiao-kang Li,Ru-quan Wang,Rui Li,Yong Wu,Zhi-ping Zhong.Ab Initio Calculation on Spectroscopic Properties and Radiative Lifetimes of Low-Lying Excited States of NaK[J].Chinese Journal of Chemical Physics,2019,32(6):667-673.
8熊超,史君杰.钢铁行业余热余能自发电标准体系构建[J].冶金动力,2020,0(3):32-35. 被引量：6
9姜海宁,张文忠,余建辉,张建伟.山西资源型城市创新环境与产业结构转型空间耦合[J].自然资源学报,2020,35(2):269-283. 被引量：68
10新型.单位点Cr-N4/C用作酸性介质中高效稳定的氧还原催化剂新进展[J].化工新型材料,2020,48(1):256-256.

Chinese Journal of Catalysis

2020年第5期

浏览历史

内容加载中请稍等...

Supported dual-atom catalysts: Preparation, characterization, and potential applications 被引量：18

同被引文献149

引证文献18

二级引证文献69

相关作者

相关机构

相关主题

浏览历史