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Revitalizing sodium-ion batteries via controllable microstructures and advanced electrolytes for hard carbon Journal article
Wang, Feng, Jiang, Zhenming, Zhang, Yanyan, Zhang, Yanlei, Li, Jidao, Wang, Huibo, Jiang, Yinzhu, Xing, Guichuan, Liu, Hongchao, Tang, Yuxin. Revitalizing sodium-ion batteries via controllable microstructures and advanced electrolytes for hard carbon[J]. eScience, 2024, 4(3), 100181.
Authors:  Wang, Feng;  Jiang, Zhenming;  Zhang, Yanyan;  Zhang, Yanlei;  Li, Jidao; et al.
Favorite | TC[WOS]:24 TC[Scopus]:15 | Submit date:2024/05/16
Controllable Microstructure  Coulombic Efficiency  Electrolyte Regulation  Hard Carbon  Sodium Storage Mechanism  Sodium-ion Batteries  
Achieving High Initial Coulombic Efficiency and Capacity in a Surface Chemical Grafting Layer of Plateau-type Sodium Titanate Journal article
Zhang, Yanlei, Li, Linwei, Wang, Feng, Wang, Huicai, Jiang, Zhenming, Lin, Zhimin, Bai, Zhengshuai, Jiang, Yinzhu, Zhang, Yanyan, Chen, Binmeng, Tang, Yuxin. Achieving High Initial Coulombic Efficiency and Capacity in a Surface Chemical Grafting Layer of Plateau-type Sodium Titanate[J]. ChemSusChem, 2024, 17(11), e202301598.
Authors:  Zhang, Yanlei;  Li, Linwei;  Wang, Feng;  Wang, Huicai;  Jiang, Zhenming; et al.
Favorite | TC[WOS]:0 TC[Scopus]:1  IF:7.5/8.4 | Submit date:2024/05/16
Heterostructure-layer  Initial Coulombic Efficiency  Plateau-type Sodium Titanate  Sodium-ion Batteries  
Ionic-conductive sodium titanate to boost sodium-ion transport kinetics of hard carbon anode in sodium-ion batteries Journal article
Wang, Feng, Li, Fan, Gong, Hao, Zhang, Yanlei, Liu, Xinyu, Jiang, Zhenming, Chen, Lian, Huang, Jianying, Zhang, Yanyan, Jiang, Yinzhu, Chen, Binmeng, Tang, Yuxin. Ionic-conductive sodium titanate to boost sodium-ion transport kinetics of hard carbon anode in sodium-ion batteries[J]. Journal of Alloys and Compounds, 2024, 981, 173668.
Authors:  Wang, Feng;  Li, Fan;  Gong, Hao;  Zhang, Yanlei;  Liu, Xinyu; et al.
Favorite | TC[WOS]:1 TC[Scopus]:1  IF:5.8/5.3 | Submit date:2024/05/02
Hard Carbon  High Rate  Ionic Conductivity  Sodium Ion Batteries  Sodium Titanate  
Towards defect-free Prussian blue-based battery electrodes Journal article
Gao, Yuting, Huang, Yao, Pan, Hongge, Ji, Lei, Wang, Li, Tang, Yuxin, Zhu, Yaofeng, Yan, Mi, Sun, Guoxing, Ni, Wenbin, Jiang, Yinzhu. Towards defect-free Prussian blue-based battery electrodes[J]. Journal of Alloys and Compounds, 2023, 950, 169886.
Authors:  Gao, Yuting;  Huang, Yao;  Pan, Hongge;  Ji, Lei;  Wang, Li; et al.
Favorite | TC[WOS]:10 TC[Scopus]:10  IF:5.8/5.3 | Submit date:2023/08/03
Nucleation And Growth  Prussian Blue Analogs  Sodium-ion Batteries  Strategies To Eliminate Defects  
Tailoring the growth of iron hexacyanoferrates for high-performance cathode of sodium-ion batteries Journal article
Xiang, Jingjing, Hao, Youchen, Gao, Yuting, Ji, Lei, Wang, Li, Sun, Guoxing, Tang, Yuxin, Zhu, Yaofeng, Jiang, Yinzhu. Tailoring the growth of iron hexacyanoferrates for high-performance cathode of sodium-ion batteries[J]. Journal of Alloys and Compounds, 2023, 946, 169284.
Authors:  Xiang, Jingjing;  Hao, Youchen;  Gao, Yuting;  Ji, Lei;  Wang, Li; et al.
Favorite | TC[WOS]:5 TC[Scopus]:5  IF:5.8/5.3 | Submit date:2023/07/19
Good Reversibility  Iron Hexacyanoferrate  Low Vacancy  Sodium Citrate  Sodium-ion Batteries  
Control of Shape and Size in Iron Fluoride Porous Sub-Microspheres: Consequences for Steric Hindrance Interaction Journal article
Song, Weibing, Lu, Hongyu, Zhao, Wenlong, Cao, Xiaofei, Yan, Lei, Zhao, Jingxin, Li, Neng, Tang, Yuxin, Hu, Jun. Control of Shape and Size in Iron Fluoride Porous Sub-Microspheres: Consequences for Steric Hindrance Interaction[J]. Frontiers in Nanotechnology, 2021, 3, 710348.
Authors:  Song, Weibing;  Lu, Hongyu;  Zhao, Wenlong;  Cao, Xiaofei;  Yan, Lei; et al.
Favorite | TC[WOS]:0 TC[Scopus]:0  IF:4.1/4.3 | Submit date:2022/05/13
Formation Mechanism  Iron-based Fluoride  Porous Sub-microspheres  Sodium Ion Batteries  Steric Hindrance  
An interface-reinforced rhombohedral Prussian blue analogue in semi-solid state electrolyte for sodium-ion battery Journal article
Xie, Bingxing, Wang, Liguang, Li, Haifeng, Huo, Hua, Cui, Can, Sun, Baoyu, Ma, Yulin, Wang, Jiajun, Yin, Geping, Zuo, Pengjian. An interface-reinforced rhombohedral Prussian blue analogue in semi-solid state electrolyte for sodium-ion battery[J]. Energy Storage Materials, 2021, 36, 99-107.
Authors:  Xie, Bingxing;  Wang, Liguang;  Li, Haifeng;  Huo, Hua;  Cui, Can; et al.
Favorite | TC[WOS]:52 TC[Scopus]:54  IF:18.9/18.4 | Submit date:2021/10/02
Interfacial Reinforcement  Prussian Blue Analogues  Rhombohedral Bulk Phase  Semi-solid State Electrolyte  Sodium Ion Batteries  
Pampas grass-inspired FeOOH nanobelts as high performance anodes for sodium ion batteries Other
2021-03-01
Authors:  Shao, Lianyi;  Wang, Shige;  Wu, Fangdan;  Shi, Xiaoyan;  Sun, Zhipeng; et al.
Favorite | TC[WOS]:24 TC[Scopus]:25 | Submit date:2021/09/10
Anode Materials  Ex-situ Techniques  Feooh Nanobelts  Hydrothermal Method  Sodium Ion Batteries  
Porous hierarchical TiO2/MoS2/RGO nanoflowers as anode material for sodium ion batteries with high capacity and stability Journal article
Ma,Jingyun, Xing,Mengdi, Yin,Longwei, San Hui,Kwan, Hui,Kwun Nam. Porous hierarchical TiO2/MoS2/RGO nanoflowers as anode material for sodium ion batteries with high capacity and stability[J]. Applied Surface Science, 2021, 536, 147735.
Authors:  Ma,Jingyun;  Xing,Mengdi;  Yin,Longwei;  San Hui,Kwan;  Hui,Kwun Nam
Favorite | TC[WOS]:32 TC[Scopus]:35  IF:6.3/5.9 | Submit date:2021/03/11
Component Matching Effect  Cycling Stability  Interconnected Network  Sodium Ion Batteries  Tio2/mos2/rgo  
Heteroatomic Interface Engineering of MOF-Derived Metal-Embedded P- And N-Codoped Zn Node Porous Polyhedral Carbon with Enhanced Sodium-Ion Storage Journal article
Zhu,Siqi, Yin,Hong, Wang,Yatong, Hui,Kwan San, Wu,Xi Lin, Mai,Wenjie, Hong,Xiaoting, Chen,Fuming, Hui,Kwun Nam. Heteroatomic Interface Engineering of MOF-Derived Metal-Embedded P- And N-Codoped Zn Node Porous Polyhedral Carbon with Enhanced Sodium-Ion Storage[J]. ACS Applied Energy Materials, 2020, 3(9), 8892-8902.
Authors:  Zhu,Siqi;  Yin,Hong;  Wang,Yatong;  Hui,Kwan San;  Wu,Xi Lin; et al.
Favorite | TC[WOS]:20 TC[Scopus]:21  IF:5.4/5.9 | Submit date:2021/03/11
Heteroatom  Mesoporous  Phosphorus  Sodium-ion Batteries  Zn Node