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On the Thermodynamics, the Role of the Carbon Cathode, and the Cycle Life of the Sodium Superoxide (NaO2) Battery

Batteries based on the cell reaction between alkali metals and oxygen are highly attractive for energy storage due to their superior theoretical energy density. However, despite continuous progress, fundamental challenges in the further development of these cell systems remain. Understanding the oxy...

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Bibliographic Details
Published in:Advanced energy materials 2014-08, Vol.4 (12), p.np-n/a
Main Authors: Bender, Conrad L., Hartmann, Pascal, Vračar, Miloš, Adelhelm, Philipp, Janek, Jürgen
Format: Article
Language:English
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Summary:Batteries based on the cell reaction between alkali metals and oxygen are highly attractive for energy storage due to their superior theoretical energy density. However, despite continuous progress, fundamental challenges in the further development of these cell systems remain. Understanding the oxygen electrode reaction and improving cycle life, while at the same time maximizing the practical energy density, are some of the most important issues that need to be addressed. Here, the product formation in aprotic sodium‐oxygen cells is studied and it is shown how cycle life and practical capacities can be improved. Different cell reactions (leading to either NaO2 or Na2O2 as discharge products) have recently been reported. To understand whether the carbon structure or the local current density has any influence on the product stoichiometry or the cell performance, several carbon materials with a broad range in properties are tested. Phase‐pure NaO2 is always found as a discharge product, but capacities range from 300 to values as high as 4000 mAh g(C)−1 depending on the type of carbon. More importantly, the cycle life of Na/O2 cells can be largely improved by shallow cycling, steadily yielding capacities of 1666 mAh g(C)−1 for at least 60 cycles using a Ketjen black carbon electrode. The cycle life of non‐aqueous sodium oxygen cells can be significantly improved by proper choice of the cycling conditions (“shallow cycling”), and the gravimetric capacity of the oxygen cathode depends on the type of carbon used. A detailed view of the thermodynamic properties of the sodium‐oxygen battery helps to explain the competition between NaO2 and Na2O2 as discharge products.
ISSN:1614-6832
1614-6840
DOI:10.1002/aenm.201301863