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Associative pyridinium electrolytes for air-tolerant redox flow batteries

Chemistry

Associative pyridinium electrolytes for air-tolerant redox flow batteries

M. E. Carrington, K. Sokołowski, et al.

This groundbreaking research by Mark E. Carrington and colleagues uncovers the redox behavior of pyridinium electrolytes in redox flow batteries, highlighting their ability to operate under air exposure. With insights into the singlet-triplet energy gap as a predictor of capacity fade and innovative findings on π-dimerization that enhance air tolerance, this work paves the way for more durable energy storage solutions.

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Playback language: English
Abstract
This paper investigates the redox behavior of pyridinium electrolytes in redox flow batteries (RFBs), focusing on their air tolerance and cycling stability. A library of extended bispyridinium compounds was synthesized and their performance was evaluated across a range of potentials. The singlet-triplet free energy gap (ΔEST) was identified as a key descriptor predicting capacity fade mechanisms. Operando NMR and EPR spectroscopies revealed two electrochemical performance regimes (narrow and wide energy gaps), both linked to free radical formation. π-dimerization was found to suppress radical reactivity with oxygen, enabling air-tolerant operation. These findings challenge previous understandings of π-dimers' role in RFBs and offer pathways for designing air-stable electrolytes.
Publisher
Nature
Published On
Nov 29, 2023
Authors
Mark E. Carrington, Kamil Sokołowski, Erlendur Jónsson, Evan Wenbo Zhao, Anton M. Graf, Israel Temprano, Jade A. McCune, Clare P. Grey, Oren A. Scherman
Tags
redox flow batteries
pyridinium electrolytes
air tolerance
cycling stability
energy gap
free radicals
π-dimerization

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