English | 繁體

Search in the results

UM

Browse/Search Results:  1-10 of 16 Help

Selected(0)Clear Items/Page:    Sort:
An electron/ion pathway reconstruction strategy enabling fast aqueous Zn2+ storage Journal article
Wang, Yuanhang, Yang, Hang, Cai, Dong, Tan, Yicheng, Li, Li, Zhang, Yiming, He, Xiaoxi, Shu, Xin, Han, Wei, Chen, Duo, Shen, Laifa. An electron/ion pathway reconstruction strategy enabling fast aqueous Zn2+ storage[J]. Materials Today Energy, 2024, 39, 101474.
Authors:  Wang, Yuanhang;  Yang, Hang;  Cai, Dong;  Tan, Yicheng;  Li, Li; et al.
Favorite | TC[WOS]:7 TC[Scopus]:7  IF:9.0/8.4 | Submit date:2024/02/22
Ion diffusIon  Reduced Graphene Oxide  Superlattice  Vanadium Oxides  Zinc-ion Battery  
MgF2 as an effective additive for improving ionic conductivity of ceramic solid electrolytes Journal article
Pengfei Zhou, Kaitong Sun, Shunping Ji, Zirui Zhao, Ying Fu, Junchao Xia, Si Wu, Yinghao Zhu, Kwun Nam Hui, Hai-Feng Li. MgF2 as an effective additive for improving ionic conductivity of ceramic solid electrolytes[J]. Materials Today Energy, 2023, 32, 101248.
Authors:  Pengfei Zhou;  Kaitong Sun;  Shunping Ji;  Zirui Zhao;  Ying Fu; et al.
Favorite | TC[WOS]:13 TC[Scopus]:15  IF:9.0/8.4 | Submit date:2023/02/07
Solid-state Battery  Solid-state Electrolytes  Nasicon  Ionic Conductivity  Additive  
Prussian Blue Analogs Cathodes for Aqueous Zinc Ion Batteries Journal article
Yuanxia Li, Jingxin Zhao, Qiang Hu, ianwei Hao, Heng Cao, Xiaomin Huang, Yu Liu, Yanyan Zhang, Dunmin Lin, Yuxin Tang, Yongqing Cai. Prussian Blue Analogs Cathodes for Aqueous Zinc Ion Batteries[J]. Materials Today Energy, 2022, 29, 101095.
Authors:  Yuanxia Li;  Jingxin Zhao;  Qiang Hu;  ianwei Hao;  Heng Cao; et al.
Favorite |   IF:9.0/8.4 | Submit date:2023/08/15
Prussian blue analogs cathodes for aqueous zinc ion batteries Journal article
Yuanxia Li, Jingxin Zhao, Qiang Hu, Tianwei Hao, Heng Cao, Xiaomin Huang, Yu Liu, Yanyan Zhang, Dunmin Lin, Yuxin Tang, Yongqing Cai. Prussian blue analogs cathodes for aqueous zinc ion batteries[J]. Materials Today Energy, 2022, 29, 101095.
Authors:  Yuanxia Li;  Jingxin Zhao;  Qiang Hu;  Tianwei Hao;  Heng Cao; et al.
Favorite | TC[WOS]:145 TC[Scopus]:147  IF:9.0/8.4 | Submit date:2022/08/22
Hexacyanoferrates  Energy Storage  Zn(2)(+)Storage  Adjustment Strategies  
Electromagnetic energy harvesters based on natural leaves for constructing self-powered systems Journal article
Yaowen Zhang, Kaijun Zhang, Yujun Shi, Zhaoyang Li, Dazhe Zhao, Yucong Pi, Yong Cui, Xiang Zhou, Yan Zhang, Junwen Zhong. Electromagnetic energy harvesters based on natural leaves for constructing self-powered systems[J]. Materials Today Energy, 2022, 29, 101133.
Authors:  Yaowen Zhang;  Kaijun Zhang;  Yujun Shi;  Zhaoyang Li;  Dazhe Zhao; et al.
Favorite | TC[WOS]:8 TC[Scopus]:9  IF:9.0/8.4 | Submit date:2022/11/07
Green Energy  Energy Harvesting  Low-quality Energy  Internet Of Things  Natural Materials  
Efficient passivation of surface defects by lewis base in lead-free tin-based perovskite solar cells Journal article
Yan, Hejin, Wang, Bowen, Yan, Xuefei, Guan, Qiye, Chen, Hongfei, Shu, Zheng, Wen, Dawei, Cai, Yongqing. Efficient passivation of surface defects by lewis base in lead-free tin-based perovskite solar cells[J]. Materials Today Energy, 2022, 27, 101038.
Authors:  Yan, Hejin;  Wang, Bowen;  Yan, Xuefei;  Guan, Qiye;  Chen, Hongfei; et al.
Favorite | TC[WOS]:24 TC[Scopus]:24  IF:9.0/8.4 | Submit date:2022/08/02
Lewis Base Additive  Organic-inorganic Halide Perovskite  Stability  Surface Functionalization  
Toward enhanced oxygen evolution on NaBH4 treated Ba0.5Sr0.5Co0.8Fe0.2O3−δ nanofilm: Insights into the facilitated surface reconstruction Journal article
Du, Xinyu, Chen, Mingpeng, Shen, Shiying, Zhou, Pengfei, Lo, Kin Ho, Pan, Hui. Toward enhanced oxygen evolution on NaBH4 treated Ba0.5Sr0.5Co0.8Fe0.2O3−δ nanofilm: Insights into the facilitated surface reconstruction[J]. Materials Today Energy, 2022, 27, 101046.
Authors:  Du, Xinyu;  Chen, Mingpeng;  Shen, Shiying;  Zhou, Pengfei;  Lo, Kin Ho; et al.
Favorite | TC[WOS]:13 TC[Scopus]:14  IF:9.0/8.4 | Submit date:2022/08/02
Active (Oxy)Hydroxide Layer  In Situ Raman Investigation  Oxygen Evolution Reaction  Pulsed Laser Deposition  
Reconstruction optimization of distorted FeOOH/Ni hydroxide for enhanced oxygen evolution reaction Journal article
Feng, Jinxian, Chen, Mingpeng, Zhou, Pengfei, Liu, Di, Chen, Yu Yun, He, Bingchen, Bai, Haoyun, Liu, Dong, Ip, Weng Fai, Chen, Shi, Liu, Detao, Feng, Wenlin, Ni, Jun, Pan, Hui. Reconstruction optimization of distorted FeOOH/Ni hydroxide for enhanced oxygen evolution reaction[J]. Materials Today Energy, 2022, 27, 101005.
Authors:  Feng, Jinxian;  Chen, Mingpeng;  Zhou, Pengfei;  Liu, Di;  Chen, Yu Yun; et al.
Favorite | TC[WOS]:44 TC[Scopus]:44  IF:9.0/8.4 | Submit date:2022/05/31
Distorted Feooh/ni Hydroxide  Electrocatalyst  Interface  Oxygen Evolution Reaction  Surface Reconstruction  
High electrochemical activity of Li2S2 linking two-dimensional tungsten boride nanosheet enables high-loading and long-lasting lithium-sulfur batteries Journal article
Zhao, Yuwei, Li, Jing, Xiang, Jianglu, Wu, Rong, Lyu, Chongguang, Ma, Huifang, Song, Xuefen, Zhang, Junran, Wang, Lin, Zha, Chenyang. High electrochemical activity of Li2S2 linking two-dimensional tungsten boride nanosheet enables high-loading and long-lasting lithium-sulfur batteries[J]. Materials Today Energy, 2022, 25, 100970.
Authors:  Zhao, Yuwei;  Li, Jing;  Xiang, Jianglu;  Wu, Rong;  Lyu, Chongguang; et al.
Favorite | TC[WOS]:21 TC[Scopus]:21  IF:9.0/8.4 | Submit date:2022/05/04
Activation Voltage  High Area Capacity  Li2s2  Long Cycling Performance  Wet Chemistry  
‘Be water’ strategy of liquid lithium sulfide enables 0.2 V potential barrier for high-performance lithium–sulfur batteries Journal article
Zhao, Y., Zhang, Z., Wu, R., Lyu, C., Zhao, X., Xu, H., Xiang, J., Zha, C., Ouyang, G., Wang, L.. ‘Be water’ strategy of liquid lithium sulfide enables 0.2 V potential barrier for high-performance lithium–sulfur batteries[J]. Materials Today Energy, 2021, 21, 100793.
Authors:  Zhao, Y.;  Zhang, Z.;  Wu, R.;  Lyu, C.;  Zhao, X.; et al.
Favorite | TC[WOS]:13 TC[Scopus]:15  IF:9.0/8.4 | Submit date:2021/12/08
Cosolvent Strategy  Electrical Conductivity  Interface Catalysis  P-orbital Of Boron  Vanadium Diboride