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Ashley Brew

Ashley Brew

OXIS Energy Ltd, UK

Title: Microgrid energy storage using Lithium-Sulfur Batteries: Feasibility of solvent-in-salt electrolytes

Biography

Biography: Ashley Brew

Abstract

Lithium-Sulfur (Li-S) batteries are considered one of the most promising technologies that could provide a generational leap in terms of energy density over current lithium ion batteries. OXIS Energy have demonstrated this by succeeding in developing Li-S batteries at 400Wh/kg. However, capacity fade at such high energy density is rapid and further research and development is needed to alleviate this. Many factors contribute to capacity fade in Li-S batteries: for example, dissolution and loss of cathode material, consumption of the electrolyte due to its reaction with lithium metal and electrical isolation of insulating sulfur and Li2S charge and discharge products. Another major issue in Li-S batteries is the ‘polysulfide shuttle’, in which reaction intermediates shuttle between the cathode and anode during charge. So-called solvent-in-salt (SIS) electrolytes are those in which the salt exceeds the solvent either by weight, by volume, or both. These unique electrolytes have demonstrated interesting properties in the literature and may solve many of the problems outlined above. SIS electrolytes inhibit intermediate dissolution due to the common ion effect, thus reducing active material loss and inhibiting the polysulfide shuttle. SIS electrolytes have also demonstrated improved lithium plating due to the high lithium-ion transference number, leading to lower rates of electrolyte depletion. These combinations of factors have resulted in these electrolytes exhibiting excellent cycle stability and coulombic efficiency in literature studies. Here we will present our work developing this type of electrolyte for R&D pouch cells and their possible use in microgrid energy storage applications. 

Recent Publications:

1. M. Wild, L. O'Neill, T. Zhang, R. Purkayastha, G. Minton, M. Marinescub and G. J. Offer, Energy Environ. Sci., 2015, 8, 3477-3494.

2. T. Zhang, M. Marinescu, L. O'Neill, M. Wild and G. Offer Phys. Chem. Chem. Phys., 2015, 17, 22581-22586.

3. A. Fotouh, D. J. Auger, K. Propp, S. Longo, M. Wild, Renewable and Sustainable Energy Reviews, 2016, 56, 1008-1021.

4.  K. Propp, M. Marinescu, D. J. Auger, L. O'Neill, A. Fotouh, K. Somasundaram, G. Offer, G. Minton, Journal of Power Sources, 2016, 328, 289-299

5.  G.Minton, L. Lue, Journal of Molecular Physics, 2016, 114, 16-17, 2477-2491