Shallow-layer pillaring of a conductive polymer in monolithic grains to drive superior zinc storageviaa cascading effect
文献类型:期刊论文
作者 | Yao, ZG; Wu, QP; Chen, KY; Liu, JJ; Li, CL |
刊名 | ENERGY & ENVIRONMENTAL SCIENCE
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出版日期 | 2020-09-01 |
期号 | 9页码:3149 |
ISSN号 | 1754-5692 |
DOI | 10.1039/d0ee01531h |
文献子类 | Article |
英文摘要 | Aqueous Zn metal batteries (ZBs) have obtained increasing attention recently owing to their low-cost and environmentally friendly nature. Unfortunately, the sluggish Zn(2+)de/intercalation in hosts often requires the nanostructural tailoring of cathode materials, which however degrades the tap density and accelerates the dissolution of active species. Herein, we propose a shallow-layer pillaring strategy to drive the superior zinc storage performance of V(2)O(5)monolithic grains without the prerequisite of intentional nanoscale attenuation. Thein situpolymerized 3,4-ethylenedioxythiophene chains only in the near-surface V(2)O(5)interlayers are sufficient to activate a cascading effect to successively open the deeper interlayers during Zn intercalation. This synergic interlayer expansion mechanism leads to a thorough and quick redox process of bulk phase V(2)O(5)even with micro-sized grains as opposed to the poor reaction kinetics in the non-pillared one. In contrast to excess pillaring or cation doping, the shallow-layer hybridization with a hydrophobic conductive polymer can suppress the dissolution of active species, reinforce the conductive contact between grains, lower the Zn(2+)diffusion barrier (0.39 eV) and absorption energy (0.17 eV), and upgrade the pseudocapacitance contribution (>67%) and Zn(2+)diffusion coefficient (1.43 x 10(-9)-1.81 x 10(-8)cm(2)s(-1)). This composite cathode enables an unprecedented cycling/rate performance (e.g.388, 367 and 351 mA h g(-1)even at 5, 8 and 10 A g(-1)respectively, and 269 mA h g(-1)after 4500 cycles at 10 A g(-1)), corresponding to high energy densities of 280.2 and 205.8 W h kg(-1)under ultrahigh power densities of 700.5 and 5960 W kg(-1), respectively. This concept of shallow-layer pillaring activation (especiallyviarich organic molecules) can be extended to more electrode systems with the preservation of the grain integrity. |
WOS关键词 | CATHODE MATERIAL ; BATTERY ; LI ; CHEMISTRY |
WOS研究方向 | Chemistry ; Energy & Fuels ; Engineering ; Environmental Sciences & Ecology |
语种 | 英语 |
出版者 | ROYAL SOC CHEMISTRY |
源URL | [http://ir.sic.ac.cn/handle/331005/27784] ![]() |
专题 | 中国科学院上海硅酸盐研究所 |
推荐引用方式 GB/T 7714 | Yao, ZG,Wu, QP,Chen, KY,et al. Shallow-layer pillaring of a conductive polymer in monolithic grains to drive superior zinc storageviaa cascading effect[J]. ENERGY & ENVIRONMENTAL SCIENCE,2020(9):3149. |
APA | Yao, ZG,Wu, QP,Chen, KY,Liu, JJ,&Li, CL.(2020).Shallow-layer pillaring of a conductive polymer in monolithic grains to drive superior zinc storageviaa cascading effect.ENERGY & ENVIRONMENTAL SCIENCE(9),3149. |
MLA | Yao, ZG,et al."Shallow-layer pillaring of a conductive polymer in monolithic grains to drive superior zinc storageviaa cascading effect".ENERGY & ENVIRONMENTAL SCIENCE .9(2020):3149. |
入库方式: OAI收割
来源:上海硅酸盐研究所
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