Facile construction of two-dimensional coordination polymers with a well-designed redox-active organic linker for improved lithium ion battery performance 被引量：3

Facile construction of two-dimensional coordination polymers with a well-designed redox-active organic linker for improved lithium ion battery performance

原文传递

导出

摘要 A well-designed redox-active organic linker,pyrazine-2,3,5,6-tetracarboxylate(H_4pztc)with brimming active sites for lithium ions storage was utilized to construct coordination polymers(CPs)via a facile hydrothermal reaction.Those two isostructural two-dimensional(2D)CPs,namely[M_2(pztc)(H_2O)_6]_n(M=Co for 1 and Ni for 2),delivered excellent reversible capacities and stable cycling performance as anodes in lithium ion batteries.As demonstrated in electrochemical studies,1 and 2 can achieve highly reversible capacities of 815 and 536 mA h g^(-1)at 200 mA g^(-1)for 150 cycles,respectively,best performed for the reported2D-CP-based anode materials.The electrochemical mechanism studies showed that the remarkable performances can be ascribed to the synergistic Li-storage redox reactions of metal centers and organic moieties.Our work highlights the opportunities of using a well-designed organic ligand to construct low-dimensional CPs as new type of electrode materials for advanced lithium ion batteries. A well-designed redox-active organic linker,pyrazine-2,3,5,6-tetracarboxylate(H_4pztc)with brimming active sites for lithium ions storage was utilized to construct coordination polymers(CPs)via a facile hydrothermal reaction.Those two isostructural two-dimensional(2D)CPs,namely[M_2(pztc)(H_2O)_6]_n(M=Co for 1 and Ni for 2),delivered excellent reversible capacities and stable cycling performance as anodes in lithium ion batteries.As demonstrated in electrochemical studies,1 and 2 can achieve highly reversible capacities of 815 and 536 mA h g^(-1)at 200 mA g^(-1)for 150 cycles,respectively,best performed for the reported2D-CP-based anode materials.The electrochemical mechanism studies showed that the remarkable performances can be ascribed to the synergistic Li-storage redox reactions of metal centers and organic moieties.Our work highlights the opportunities of using a well-designed organic ligand to construct low-dimensional CPs as new type of electrode materials for advanced lithium ion batteries.

作者 Jingwei Liu Lin Zhang Huanhuan Li Peng Zhao Peng Ren Wei Shi Peng Cheng

机构地区 Key Laboratory of Advanced Energy Materials Chemistry of Ministry of Education School of Science Collaborative Innovation Center of Chemical Science and Engineering (Tianjin)

出处《Science China Chemistry》 SCIE EI CAS CSCD 2019年第5期602-608,共7页 中国科学（化学英文版）

基金 supported by the National Natural Science Foundation of China(21622105,21501071,21421001) Shenzhen Fundamental Research Project(JCYJ20160525164227350) the Ministry of Education of China(B12015) the Natural Science Foundation of Tianjin(18JCJQJC47200)

关键词 two-dimensional COORDINATION POLYMERS ANODE materials LITHIUM ion battery two-dimensional coordination polymers anode materials lithium ion battery

分类号 O631 [理学—高分子化学] TM912 [理学—化学]

引文网络
相关文献

同被引文献14

1Yunping Wen,Yao Liu,Duan Bin,Zhuo Wang,Congxiao Wang,Yuliang Cao,Xinping Ai,Yongyao Xia.High performance TiP_2O_7 nanoporous microsphere as anode material for aqueous lithium-ion batteries[J].Science China Chemistry,2019,62(1):118-125. 被引量：3
2Yi-Lun Ying,Chan Cao,Yong-Xu Hu,Yi-Tao Long.A single biomolecule interface for advancing the sensitivity, selectivity and accuracy of sensors[J].National Science Review,2018,5(4):450-452. 被引量：8
3Ying-Zhi Sun,Jia-Qi Huang,Chen-Zi Zhao,Qiang Zhang.A review of solid electrolytes for safe lithium-sulfur batteries[J].Science China Chemistry,2017,60(12):1508-1526. 被引量：16
4Jun Mei,Yuanwen Zhang,Ting Liao,Ziqi Sun,Shi Xue Dou.Strategies for improving the lithium-storage performance of 2D nanomaterials[J].National Science Review,2018,5(3):389-416. 被引量：12
5Xiaobing Lou,Yanqun Ning,Chao Li,Xiaoshi Hu,Ming Shen,Bingwen Hu.Bimetallic zeolite imidazolate framework for enhanced lithium storage boosted by the redox participation of nitrogen atoms[J].Science China Materials,2018,61(8):1040-1048. 被引量：6
6Yumei Luo,Lixian Sun,Fen Xu,Siyue Wei,Qingyong Wang,Hongliang Peng,Chonglin Chen.Cobalt(Ⅱ)coordination polymers as anodes for lithium-ion batteries with enhanced capacity and cycling stability[J].Journal of Materials Science & Technology,2018,34(8):1412-1418. 被引量：2
7Dong-Bo Zhang,Xing-Ju Zhao,Gotthard Seifert,Kinfai Tse,Junyi Zhu.Twist-driven separation of p-type and n-type dopants in single-crystalline nanowires[J].National Science Review,2019,6(3):532-539. 被引量：2
8Chen-Zi Zhao,Hui Duan,Jia-Qi Huang,Juan Zhang,Qiang Zhang,Yu-Guo Guo,Li-Jun Wan.Designing solid-state interfaces on lithium-metal anodes: a review[J].Science China Chemistry,2019,62(10):1286-1299. 被引量：16
9John B.Goodenough,Hongcai Gao.A perspective on the Li-ion battery[J].Science China Chemistry,2019,62(12):1555-1556. 被引量：15
10Shasha Zheng,Qing Li,Huaiguo Xue,Huan Pang,Qiang Xu.A highly alkaline-stable metal oxide@metal-organic framework composite for high-performance electrochemical energy storage[J].National Science Review,2020,7(2):305-314. 被引量：27

引证文献3

1Min Du,Feng Zhang,Xiaofei Zhang,Wentao Dong,Yuanhua Sang,Jianjun Wang,Hong Liu,Shuhua Wang.Calcium ion pinned vanadium oxide cathode for high-capacity and long-life aqueous rechargeable zinc-ion batteries[J].Science China Chemistry,2020,63(12):1767-1776. 被引量：2
2赵为为,金贝贝,江梦月,刘淑娟,赵强.基于碳化钛衍生的一维纳米材料的制备与应用[J].中国科学：化学,2020,50(12):1755-1768. 被引量：2
3Zhoujia Liu,Fenfen Zheng,Weiwei Xiong,Xiaogang Li,Aihua Yuan,Huan Pang.Strategies to improve electrochemical performances of pristine metal‐organic frameworks‐based electrodes for lithium/sodium‐ion batteries[J].SmartMat,2021,2(4):488-518. 被引量：7

二级引证文献11

1Hanchen Ye,Cheng Zhang,Yang Li,Wenjie Zhang,Kun Zhang,Bingzhong Li,Wenchao Hua,Kuaibing Wang,Kaihua Xu.Advanced covalent-organic framework materials for sodium-ion battery[J].Progress in Natural Science:Materials International,2023,33(6):754-766.
2Xu Yang,Qiu‐Xia Li,Shao‐Yi Chi,Hong‐Fang Li,Yuan‐Biao Huang,Rong Cao.Hydrophobic perfluoroalkane modified metal‐organic frameworks for the enhanced electrocatalytic reduction of CO_(2)[J].SmartMat,2022,3(1):163-172. 被引量：3
3Yong Guo,Shichao Wu,Yan-Bing He,Feiyu Kang,Liquan Chen,Hong Li,Quan-Hong Yang.Solid-state lithium batteries: Safety and prospects[J].eScience,2022,2(2):138-163. 被引量：19
4Jing Zhu,Xiaoyu Chen,Ai Qin Thang,Fei‐Long Li,Dong Chen,Hongbo Geng,Xianhong Rui,Qingyu Yan.Vanadium-based metal-organic frameworks and their derivatives for electrochemical energy conversion and storage[J].SmartMat,2022,3(3):384-416. 被引量：3
5宋旸,梁宏宝,陈忠喜,马骏.纳米ZnO颗粒对SBR活性污泥硝化作用的影响及机制研究[J].功能材料,2022,53(8):8134-8139. 被引量：3
6Zhi-Hao Su,Run-Hao Wang,Jiong-Hao Huang,Rui Sun,Zhao-Xia Qin,Yu-Fei Zhang,Hao-Sen Fan.Silver vanadate(Ag_(0.33)V_(2)O_(5))nanorods from Ag intercalated vanadium pentoxide for superior cathode of aqueous zinc-ion batteries[J].Rare Metals,2022,41(8):2844-2852. 被引量：9
7Shanjing Liu,Xiaohan Wan,Yue Sun,Shiqi Li,Xingmei Guo,Ming Li,Rui Yin,Qinghong Kong,Jing Kong,Junhao Zhang.Cobalt-based multicomponent nanoparticles supported on N-doped graphene as advanced cathodic catalyst for zinc-air batteries[J].International Journal of Minerals,Metallurgy and Materials,2022,29(12):2212-2220. 被引量：1
8黄鹏,王欣媛,郝芹,周济,徐彩霞.多级纳米花球状聚多巴胺-钼氧化物复合材料用于宽电压窗口锌离子存储[J].聊城大学学报（自然科学版）,2023,36(1):85-92. 被引量：1
9高桂红,刘福园,李珅珅,巫湘坤,刘艳侠.二元导电剂对锂浆料电池性能的影响[J].储能科学与技术,2023,12(11):3299-3306. 被引量：1
10Yue Qian,Zhoujia Liu,Haixin Song,Ruize Yin,Hanni Yang,Siyang Li,Weiwei Xiong,Saisai Yuan,Junhao Zhang,Huan Pang.Imide-based covalent organic framework with excellent cyclability as an anode material for lithium-ion battery[J].Chinese Chemical Letters,2024,35(6):206-210.

1Shitong WANG,Yong YANG,Yanhao DONG,Zhongtai ZHANG,Zilong TANG.Recent progress in Ti-based nanocomposite anodes for lithium ion batteries[J].Journal of Advanced Ceramics,2019,8(1):1-18. 被引量：14
2Aibassov Yerkin,Yemelyanova Valentina,Savizky Ruben,Askarova Gauhar.The Laws of the Chemical Psychology[J].Journal of Chemistry and Chemical Engineering,2018,12(3):121-123.
3Mengmeng Zhen,Xintao Zuo,Juan Wang,Cheng Wang.An integrated cathode with bi-functional catalytic effect for excellent-performance lithium-sulfur batteries[J].Nano Research,2019,12(5):1017-1024. 被引量：3
4Shenghui Shen,Shengjue Deng,Yu Zhong,Jianbo Wu,Xiuli Wang,Xinhui Xia,Jiangping Tu.Binder-free carbon fiber/TiNb2O7 composite electrode as superior high-rate anode for lithium ions batteries[J].Chinese Chemical Letters,2017,28(12):2219-2222. 被引量：1
5Shaohua Guo,Haoshen Zhou.High-energy Mn-based layered cathodes for sodium-ion batteries[J].Science Bulletin,2019,64(3):149-150.
6Min Hui Yap,Kam Loon Fow,George Zheng Chen.Synthesis and applications of MOF-derived porous nanostructures[J].Green Energy & Environment,2017,2(3):218-245. 被引量：15
7Xiao-Fei Yu,Dong-Xu Tian,Wen-Cui Li,Bin He,Yu Zhang,Zhi-Yuan Chen,An-Hui Lu.One-pot synthesis of highly conductive nickel-rich phosphide/CNTs hybrid as a polar sulfur host for high-rate and long-cycle Li-S battery[J].Nano Research,2019,12(5):1193-1197. 被引量：5
8Peng Wang,Xiaobing Lou,Chao Li,Xiaoshi Hu,Qi Yang,Bingwen Hu.One-Pot Synthesis of Co-Based Coordination Polymer Nanowire for Li-Ion Batteries with Great Capacity and Stable Cycling Stability[J].Nano-Micro Letters,2018,10(2):3-11. 被引量：3
9Haoliang LI,Yicheng SONG,Bo LU,Junqian ZHANG.Effects of stress dependent electrochemical reaction on voltage hysteresis of lithium ion batteries[J].Applied Mathematics and Mechanics(English Edition),2018,39(10):1453-1464. 被引量：3
10WU Yi-Wei,HONG Zhong-Zhu,ZHU Mei-Hua,GUO Hong-Xu,YING Shao-Ming.CoNi_2S_4 Microspheres Prepared by One-pot Hydrothermal Reaction as Supercapacitor[J].Chinese Journal of Structural Chemistry,2019,38(1):83-88. 被引量：1

Science China Chemistry

2019年第5期

浏览历史

内容加载中请稍等...

Facile construction of two-dimensional coordination polymers with a well-designed redox-active organic linker for improved lithium ion battery performance 被引量：3

同被引文献14

引证文献3

二级引证文献11

相关作者

相关机构

相关主题

浏览历史