High-Performance Full Sodium Cells Based on MgO-Treated P2-Type Na0.67(Mn0.5Fe0.5)1−xCoxO2 Cathodes

Herein, we design a cathode material based on layered Na2/3(Mn1/2Fe1/2)O2 for practical application by combining the Co substitution and MgO treatment strategies. The oxides are prepared via solid-state reactions at 900 °C. The structure, morphology, and oxidation state of transition metal ions for...

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Published inBatteries (Basel) Vol. 9; no. 10; p. 497
Main Authors Taskiran, Nermin, Altundag, Sebahat, Koleva, Violeta, Altin, Emine, Arshad, Muhammad, Avci, Sevda, Ates, Mehmet Nurullah, Altin, Serdar, Stoyanova, Radostina
Format Journal Article
LanguageEnglish
Published Basel MDPI AG 01.10.2023
Subjects
Additives
Carbon
Cathodes
co substitution
Cycles
Electrode materials
Electrodes
layered oxides
Magnesium oxide
Morphology
Na0.67MnO2
operando XAS
Oxidation
Protective coatings
Sodium
sodium-ion batteries
Stability
Transition metals
Valence
X ray photoelectron spectroscopy
United States > US
Turkey
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Summary:Herein, we design a cathode material based on layered Na2/3(Mn1/2Fe1/2)O2 for practical application by combining the Co substitution and MgO treatment strategies. The oxides are prepared via solid-state reactions at 900 °C. The structure, morphology, and oxidation state of transition metal ions for Co-substituted and MgO-treated oxides are carefully examined via X-ray diffraction, IR and Raman spectroscopies, FESEM with EDX, specific surface area measurement, and XPS spectroscopy. The ability of oxides to store sodium reversibly is analyzed within a temperature range of 10 to 50 °C via CV experiments, galvanostatic measurements, and EIS, using half and full sodium ion cells. The changes in the local structure and oxidation state of transition metal ions during Na+ intercalation are monitored via operando XAS experiments. It is found that the Co substituents have a positive impact on the rate capability of layered oxides, while Mg additives lead to a strong increase in the capacity and an enhancement of the cycling stability. Thus, the highest capacity is obtained for 2 at.%-MgO-treated Na2/3(Mn1/2Fe1/2)0.9Co0.1O2 (175 mAh/g, with a capacity fade of 28% after 100 cycles). In comparison with Co substituents, the Mg treatment has a crucial role in the improvement of the lattice stability during the cycling process. The best electrode materials, with a chemical formula of 2 at.%-MgO treated Na2/3(Mn1/2Fe1/2)0.9Co0.1O2, were also used for the full cells design, with hard carbon as an anode. In the voltage window of 2–4 V, the capacity of the cells was obtained as 78 mAh/g and 51 mAh/g for applied current densities of 12 mA/g and 60 mA/g, respectively.
ISSN:2313-0105
2313-0105
DOI:10.3390/batteries9100497