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Boosting High-Rate Zinc-Storage Performance by the Rational Design of Mn 2 O 3 Nanoporous Architecture Cathode
Nano-Micro Letters ( IF 31.6 ) Pub Date : 2019-12-31 , DOI: 10.1007/s40820-019-0351-4 Danyang Feng 1 , Tu-Nan Gao 1 , Ling Zhang 2 , Bingkun Guo 3 , Shuyan Song 4 , Zhen-An Qiao 1 , Sheng Dai 5
中文翻译:
合理设计Mn 2 O 3 纳米多孔结构阴极提高高倍率储锌性能
更新日期:2020-01-04
Nano-Micro Letters ( IF 31.6 ) Pub Date : 2019-12-31 , DOI: 10.1007/s40820-019-0351-4 Danyang Feng 1 , Tu-Nan Gao 1 , Ling Zhang 2 , Bingkun Guo 3 , Shuyan Song 4 , Zhen-An Qiao 1 , Sheng Dai 5
Affiliation
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Highly crystalline Mn2O3 materials with tunable pore sizes are obtained and employed as high-performance cathode materials for reversible aqueous Zn-ion battery.
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The Zn/Mn2O3 battery exhibits significantly improved rate capability and remarkable cycling durability due to the introduction of nanoporous architecture.
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The Zn2+/H+ intercalations mechanism is put forward for the Zn/Mn2O3 battery.
中文翻译:
合理设计Mn 2 O 3 纳米多孔结构阴极提高高倍率储锌性能
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获得了孔径可调的高结晶Mn 2 O 3材料,并将其用作可逆水系锌离子电池的高性能正极材料。 -
由于纳米多孔结构的引入,Zn/Mn 2 O 3电池表现出显着提高的倍率性能和显着的循环耐久性。 -
提出了Zn/Mn 2 O 3电池的Zn 2+ /H +嵌入机制。