A cobalt and nickel co-modified layered P2-Na2/3Mn1/2Fe1/2O2 with excellent cycle stability for high-energy density sodium-ion batteries
Considering the abundant sodium resources, sodium-ion batteries (SIBs) demonstrate great potential in large-scale electrochemical energy storage sectors which capacity and cycle stability is highly dependent on their electrode materials. Layered P2-type Mn-Fe-based oxide has been considered as one o...
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sg-ntu-dr.10356-1513492021-07-09T02:02:12Z A cobalt and nickel co-modified layered P2-Na2/3Mn1/2Fe1/2O2 with excellent cycle stability for high-energy density sodium-ion batteries Chu, Shiyong Chen, Yubo Wang, Jie Dai, Jie Liao, Kaiming Zhou, Wei Shao, Zongping School of Materials Science and Engineering Engineering::Materials Sodium Ion Batteries Layered Cathode Considering the abundant sodium resources, sodium-ion batteries (SIBs) demonstrate great potential in large-scale electrochemical energy storage sectors which capacity and cycle stability is highly dependent on their electrode materials. Layered P2-type Mn-Fe-based oxide has been considered as one of the most promising cathodes for SIBs, while its unsatisfactory cycle performance and low energy density strongly limit practical application. Here, a Co/Ni modification strategy is proposed to optimize P2-Na2/3Mn1/2Fe1/2O2 (MF) from both aspects of reversible capacity and cycle stability, leading to the design of a new P2-Na2/3Mn1/2Fe1/4Co1/8Ni1/8O2 (MFCN). In this new layered P2-type material, the introduction of Co effectively inhibits the irreversibility of the material, and the introduction of Ni relieves the Jahn-Teller effect and reduces Mn dissolution. The simultaneous introduction of Co and Ni effectively improves the cycle stability of the electrode, indicated by the increase of the capacity retention rate from 51.5% for MF to 87.4% for MFCN over 100 discharge-charge cycles at the same current density of 130 mA g−1. Meanwhile, the introduction of Ni effectively increases the discharge voltage with the middle discharge voltage increasing from 2.8 V (MF) to 3.3 V (MFCN), thereby improving the energy density of the electrode. All above features make the new material highly promising for use as a cathode material in practical SIBs. This work was financially supported by the National Key R&D Program of China (Grant No. 2018YFB0905400), the Six Talent Peaks Project of Jiangsu Province (Grant No. XNY-CXTD-001), Jiangsu Natural Science Foundation for Distinguished Young Scholars (Grant No. BK20170043). 2021-07-09T02:02:12Z 2021-07-09T02:02:12Z 2018 Journal Article Chu, S., Chen, Y., Wang, J., Dai, J., Liao, K., Zhou, W. & Shao, Z. (2018). A cobalt and nickel co-modified layered P2-Na2/3Mn1/2Fe1/2O2 with excellent cycle stability for high-energy density sodium-ion batteries. Journal of Alloys and Compounds, 775, 383-392. https://dx.doi.org/10.1016/j.jallcom.2018.10.150 0925-8388 https://hdl.handle.net/10356/151349 10.1016/j.jallcom.2018.10.150 2-s2.0-85054830030 775 383 392 en Journal of Alloys and Compounds © 2018 Published by Elsevier B.V. All rights reserved. |
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Engineering::Materials Sodium Ion Batteries Layered Cathode Chu, Shiyong Chen, Yubo Wang, Jie Dai, Jie Liao, Kaiming Zhou, Wei Shao, Zongping A cobalt and nickel co-modified layered P2-Na2/3Mn1/2Fe1/2O2 with excellent cycle stability for high-energy density sodium-ion batteries |
| description |
Considering the abundant sodium resources, sodium-ion batteries (SIBs) demonstrate great potential in large-scale electrochemical energy storage sectors which capacity and cycle stability is highly dependent on their electrode materials. Layered P2-type Mn-Fe-based oxide has been considered as one of the most promising cathodes for SIBs, while its unsatisfactory cycle performance and low energy density strongly limit practical application. Here, a Co/Ni modification strategy is proposed to optimize P2-Na2/3Mn1/2Fe1/2O2 (MF) from both aspects of reversible capacity and cycle stability, leading to the design of a new P2-Na2/3Mn1/2Fe1/4Co1/8Ni1/8O2 (MFCN). In this new layered P2-type material, the introduction of Co effectively inhibits the irreversibility of the material, and the introduction of Ni relieves the Jahn-Teller effect and reduces Mn dissolution. The simultaneous introduction of Co and Ni effectively improves the cycle stability of the electrode, indicated by the increase of the capacity retention rate from 51.5% for MF to 87.4% for MFCN over 100 discharge-charge cycles at the same current density of 130 mA g−1. Meanwhile, the introduction of Ni effectively increases the discharge voltage with the middle discharge voltage increasing from 2.8 V (MF) to 3.3 V (MFCN), thereby improving the energy density of the electrode. All above features make the new material highly promising for use as a cathode material in practical SIBs. |
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School of Materials Science and Engineering |
| author_facet |
School of Materials Science and Engineering Chu, Shiyong Chen, Yubo Wang, Jie Dai, Jie Liao, Kaiming Zhou, Wei Shao, Zongping |
| format |
Article |
| author |
Chu, Shiyong Chen, Yubo Wang, Jie Dai, Jie Liao, Kaiming Zhou, Wei Shao, Zongping |
| author_sort |
Chu, Shiyong |
| title |
A cobalt and nickel co-modified layered P2-Na2/3Mn1/2Fe1/2O2 with excellent cycle stability for high-energy density sodium-ion batteries |
| title_short |
A cobalt and nickel co-modified layered P2-Na2/3Mn1/2Fe1/2O2 with excellent cycle stability for high-energy density sodium-ion batteries |
| title_full |
A cobalt and nickel co-modified layered P2-Na2/3Mn1/2Fe1/2O2 with excellent cycle stability for high-energy density sodium-ion batteries |
| title_fullStr |
A cobalt and nickel co-modified layered P2-Na2/3Mn1/2Fe1/2O2 with excellent cycle stability for high-energy density sodium-ion batteries |
| title_full_unstemmed |
A cobalt and nickel co-modified layered P2-Na2/3Mn1/2Fe1/2O2 with excellent cycle stability for high-energy density sodium-ion batteries |
| title_sort |
cobalt and nickel co-modified layered p2-na2/3mn1/2fe1/2o2 with excellent cycle stability for high-energy density sodium-ion batteries |
| publishDate |
2021 |
| url |
https://hdl.handle.net/10356/151349 |
| _version_ |
1705151283488358400 |