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A redox shuttle to facilitate oxygen reduction in the lithium air battery

A redox shuttle to facilitate oxygen reduction in the lithium air battery
A redox shuttle to facilitate oxygen reduction in the lithium air battery
A novel design of the non-aqueous lithium air cell is presented with a demonstration of a new reaction concept, involving a soluble redox shuttle to catalyse oxygen reduction. In principle, this can relieve the requirement for fast diffusion of molecular oxygen from the air interface to the positive electrode. To demonstrate this concept, ethyl viologen ditriflate was dissolved in BMPTFSI, reduced at a carbon electrode and regenerated by aspiration with oxygen. Useful shuttle behaviour, confirmed by several reduction–oxidation cycles, was observed in the case where the electrolyte contained at least 0.3 M lithium salt. The beneficial effect of the salt was attributed to its critical role in converting superoxide, which would otherwise destroy the shuttle, into the more desirable product of oxygen reduction, lithium peroxide.
1388-2481
74-76
Lacey, Matthew J.
d474e53b-ac9c-4e75-abe9-cdd1d9d549b0
Frith, James T.
6f9df7da-00ca-4b23-b18c-b1f66d013250
Owen, John R.
067986ea-f3f3-4a83-bc87-7387cc5ac85d
Lacey, Matthew J.
d474e53b-ac9c-4e75-abe9-cdd1d9d549b0
Frith, James T.
6f9df7da-00ca-4b23-b18c-b1f66d013250
Owen, John R.
067986ea-f3f3-4a83-bc87-7387cc5ac85d

Lacey, Matthew J., Frith, James T. and Owen, John R. (2013) A redox shuttle to facilitate oxygen reduction in the lithium air battery. Electrochemistry Communications, 26 (1), 74-76. (doi:10.1016/j.elecom.2012.10.009).

Record type: Article

Abstract

A novel design of the non-aqueous lithium air cell is presented with a demonstration of a new reaction concept, involving a soluble redox shuttle to catalyse oxygen reduction. In principle, this can relieve the requirement for fast diffusion of molecular oxygen from the air interface to the positive electrode. To demonstrate this concept, ethyl viologen ditriflate was dissolved in BMPTFSI, reduced at a carbon electrode and regenerated by aspiration with oxygen. Useful shuttle behaviour, confirmed by several reduction–oxidation cycles, was observed in the case where the electrolyte contained at least 0.3 M lithium salt. The beneficial effect of the salt was attributed to its critical role in converting superoxide, which would otherwise destroy the shuttle, into the more desirable product of oxygen reduction, lithium peroxide.

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Published date: January 2013
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Organisations: Electrochemistry

Identifiers

Local EPrints ID: 347025
URI: http://eprints.soton.ac.uk/id/eprint/347025
DOI: doi:10.1016/j.elecom.2012.10.009
ISSN: 1388-2481
PURE UUID: 8ea9f7a5-6e61-4575-b24a-c78723216abf
ORCID for John R. Owen: ORCID iD orcid.org/0000-0002-4938-3693

Catalogue record

Date deposited: 17 Jan 2013 14:05
Last modified: 15 Mar 2024 02:44

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Contributors

Author: Matthew J. Lacey
Author: James T. Frith
Author: John R. Owen ORCID iD

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