Associative pyridinium electrolytes for air-tolerant redox flow batteries

Carrington, Mark E.; Sokołowski, Kamil; Jónsson, Erlendur; Zhao, Evan Wenbo; Graf, Anton M.; Temprano, Israel; McCune, Jade A.; Grey, Clare P.; Scherman, Oren A.

Associative pyridinium electrolytes for air-tolerant redox flow batteries

Mark E. Carrington, Kamil Sokołowski, Erlendur Jónsson, Evan Wenbo Zhao, Anton M. Graf, Israel Temprano, Jade A. McCune, Clare P. Grey () and Oren A. Scherman ()
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Mark E. Carrington: University of Cambridge
Kamil Sokołowski: University of Cambridge
Erlendur Jónsson: University of Cambridge
Evan Wenbo Zhao: University of Cambridge
Anton M. Graf: University of Cambridge
Israel Temprano: University of Cambridge
Jade A. McCune: University of Cambridge
Clare P. Grey: University of Cambridge
Oren A. Scherman: University of Cambridge

Nature, 2023, vol. 623, issue 7989, 949-955

Abstract: Abstract Pyridinium electrolytes are promising candidates for flow-battery-based energy storage1–4. However, the mechanisms underlying both their charge–discharge processes and overall cycling stability remain poorly understood. Here we probe the redox behaviour of pyridinium electrolytes under representative flow battery conditions, offering insights into air tolerance of batteries containing these electrolytes while providing a universal physico-chemical descriptor of their reversibility. Leveraging a synthetic library of extended bispyridinium compounds, we track their performance over a wide range of potentials and identify the singlet–triplet free energy gap as a descriptor that successfully predicts the onset of previously unidentified capacity fade mechanisms. Using coupled operando nuclear magnetic resonance and electron paramagnetic resonance spectroscopies5,6, we explain the redox behaviour of these electrolytes and determine the presence of two distinct regimes (narrow and wide energy gaps) of electrochemical performance. In both regimes, we tie capacity fade to the formation of free radical species, and further show that π-dimerization plays a decisive role in suppressing reactivity between these radicals and trace impurities such as dissolved oxygen. Our findings stand in direct contrast to prevailing views surrounding the role of π-dimers in redox flow batteries1,4,7–11 and enable us to efficiently mitigate capacity fade from oxygen even on prolonged (days) exposure to air. These insights pave the way to new electrolyte systems, in which reactivity of reduced species is controlled by their propensity for intra- and intermolecular pairing of free radicals, enabling operation in air.

Date: 2023
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DOI: 10.1038/s41586-023-06664-7

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