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Elucidation of Parasitic Reaction Mechanisms at Interfaces in Na–O2Batteries
- Source :
- Chemistry of Materials; August 2023, Vol. 35 Issue: 15 p5945-5952, 8p
- Publication Year :
- 2023
-
Abstract
- Sodium-containing batteries have the potential to address many of the challenges faced in the ongoing development of enhanced energy storage devices. Sodium is inexpensive and earth abundant, and aprotic Na–O2batteries, in particular, have gravimetric energy densities significantly exceeding those of Li-ion devices. However, poor functional cell lifespans present a significant obstacle to the development of Na–O2cells, with parasitic side reactions involving the NaO2discharge products, leading to a rapid decline in cell performance. These parasitic reactions are hypothesized to occur through two main pathways: (i) deleterious dissolution of NaO2into the electrolyte during periods of cell idling and (ii) disproportionation of NaO2in the near-surface region to form Na-rich species (Na1+xO2) on the cathode. To formulate practical strategies to suppress these processes, in turn, the development of fundamental, molecular-level mechanistic understanding is essential. In this contribution, such mechanistic insights are elucidated by coupling density functional theory calculations with experimental observations to study the surface chemistry of the NaO2discharge product. First, a series of ab initiosurface phase diagrams are constructed to determine the structure of the NaO2surfaces under realistic operating conditions, whereby an inverse relationship between surface coordination and surface energy is determined. Next, a molecular surface dissolution analysis is performed for the identified surface terminations, demonstrating a further inverse relationship between surface energy and the thermodynamic barrier for dissolution. Finally, a study of the thermodynamics of thin-film formation of sodium oxides over the NaO2discharge product is carried out and suggests that an electrochemical reduction reaction, rather than an inherent chemical disproportionation, forms the observed Na-rich species in the near-surface region under high discharge overpotentials. From these insights, we suggest future studies that may yield practical design changes to improve stability and extend the lifespan of Na–O2batteries.
Details
- Language :
- English
- ISSN :
- 08974756
- Volume :
- 35
- Issue :
- 15
- Database :
- Supplemental Index
- Journal :
- Chemistry of Materials
- Publication Type :
- Periodical
- Accession number :
- ejs63612405
- Full Text :
- https://doi.org/10.1021/acs.chemmater.3c00850