Ramachandran, H.
, Mu, E.
, Lomeli, E.
, Braun, A.
, Goto, M.
, Hsu, K.
, Liu, J.
, Jiang, Z.
, Lim, K.
, Busse, G.
, Moritz, B.
, Kas, J.
, Vinson, J.
, Rehr, J.
, Park, J.
, Abate, I.
, Shimakawa, Y.
, Solomon, E.
, Yang, W.
, Gent, W.
, Devereaux, T.
and Chueh, W.
(2025),
A formal Fe(III)/(V) redox couple in an intercalation electrode, Nature Materials, [online], https://doi.org/10.1038/s41563-025-02356-x, https://tsapps.nist.gov/publication/get_pdf.cfm?pub_id=957926
(Accessed November 21, 2025)
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A formal Fe(III)/(V) redox couple in an intercalation electrode
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Author(s)
Hari Ramachandran, Edward Mu, Eder Lomeli, Augustin Braun, Masato Goto, Kuan Hsu, Jue Liu, Zhelong Jiang, Kipil Lim, Grace Busse, Brian Moritz, Joshua Kas, , John Rehr, Jungjin Park, Iwnetim Abate, Yuichi Shimakawa, Edward Solomon, Wanli Yang, William Gent, Thomas Devereaux, William Chueh
Abstract
Iron redox cycling between low-valent oxidation states of FeII and FeIII drives crucial processes in nature. The FeII/III redox couple charge compensates the cycling of lithium iron phosphate, a positive electrode (cathode) for lithium-ion batteries. High-valent iron redox couples, involving formal oxidation higher than FeIII, could deliver higher electrochemical potentials and energy densities. However, because of the instability of high-valent Fe electrodes, they have proven difficult to probe and exploit in intercalation systems. Here we report and characterize a formal FeIII/V redox couple by revisiting the charge compensation mechanism of (de)lithiation in Li4FeSbO6. Valence-sensitive experimental and computational core-level spectroscopy reveal a direct transition from FeIII (3d5) to a negative-charge-transfer FeV (3d5L2) ground state on delithiation, without forming FeIV, or oxygen dimers. We identify that the cation ordering in Li4FeSbO6 drives a templated phase transition to stabilize the unique FeV species and demonstrate that disrupting cation ordering suppresses the FeIII/V redox couple. Exhibiting resistance to calendar aging, high operating potential and low voltage hysteresis, the FeIII/V redox couple in Li4FeSbO6 provides a framework for developing sustainable, Fe-based intercalation cathodes for high-voltage applications.Citation
Nature Materials
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Created October 15, 2025, Updated November 20, 2025