Issue 11, 2017

Design of fast ion conducting cathode materials for grid-scale sodium-ion batteries

Abstract

The obvious cost advantage as well as attractive electrochemical properties, including excellent cycling stability and the potential of high rate performance, make sodium-ion batteries prime candidates in the race to technically and commercially enable large-scale electrochemical energy storage. In this work, we apply our bond valence site energy modelling method to further the understanding of rate capabilities of a wide range of potential insertion-type sodium-ion battery cathode materials. We demonstrate how a stretched exponential function permits us to systematically quantify the rate performance, which in turn reveals guidelines for the design of novel sodium-ion battery chemistries suitable for high power, grid-scale applications. Starting from a diffusion relaxation model, we establish a semi-quantitative prediction of the rate-performance of half-cells from the structure of the cathode material that factors in dimensionality of Na+ ion migration pathways, the height of the migration barriers and the crystallite size of the active material. With the help of selected examples, we also illustrate the respective roles of unoccupied low energy sites within the pathway and temperature towards the overall rate capability of insertion-type cathode materials.

Graphical abstract: Design of fast ion conducting cathode materials for grid-scale sodium-ion batteries

Supplementary files

Article information

Article type
Paper
Submitted
03 Jan 2017
Accepted
21 Feb 2017
First published
21 Feb 2017
This article is Open Access
Creative Commons BY-NC license

Phys. Chem. Chem. Phys., 2017,19, 7506-7523

Design of fast ion conducting cathode materials for grid-scale sodium-ion batteries

L. L. Wong, H. Chen and S. Adams, Phys. Chem. Chem. Phys., 2017, 19, 7506 DOI: 10.1039/C7CP00037E

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