Spin Matters: A Multidisciplinary Roadmap to Understanding Spin Effects in Oxygen Evolution Reaction During Water Electrolysis

Emma van der Minne; Priscila Vensaus; Vadim Ratovskii; Seenivasan Hariharan; Jan Behrends; Cesare Franchini; Jonas Fransson; Sarnjeet S. Dhesi; Felix Gunkel; Florian Gossing; Georgios Katsoukis; Ulrike I. Kramm; Magalí Lingenfelder; Qianqian Lan; Yury V. Kolen'ko; Yang Li; Ramsundar Rani Mohan; Jeffrey McCord; Lingmei Ni; Eva Pavarini; Rossitza Pentcheva; David H. Waldeck; Michael Verhage; Anke Yu; Zhichuan J. Xu; Piero Torelli; Silvia Mauri; Narcis Avarvari; Anja Bieberle-Hütter; Christoph Baeumer

doi:10.1002/aenm.202503556

Spin Matters: A Multidisciplinary Roadmap to Understanding Spin Effects in Oxygen Evolution Reaction During Water Electrolysis

Emma van der Minne^*
, Priscila Vensaus^*
, Vadim Ratovskii
, Seenivasan Hariharan
, Jan Behrends
, Cesare Franchini
, Jonas Fransson
, Sarnjeet S. Dhesi
, Felix Gunkel
, Florian Gossing
, Georgios Katsoukis
, Ulrike I. Kramm
, Magalí Lingenfelder
, Qianqian Lan
, Yury V. Kolen'ko
, Yang Li
, Ramsundar Rani Mohan
, Jeffrey McCord
, Lingmei Ni
, Eva Pavarini

Rossitza Pentcheva, David H. Waldeck, Michael Verhage, Anke Yu, Zhichuan J. Xu, Piero Torelli, Silvia Mauri, Narcis Avarvari, Anja Bieberle-Hütter, Christoph Baeumer^*

^*Corresponding author for this work

Research output: Contribution to journal › Review article › Academic › peer-review

1 Citation (Scopus)

3 Downloads (Pure)

Abstract

A central challenge in water electrolysis lies with the oxygen evolution reaction (OER) where the formation of molecular oxygen (O₂) is hindered by the constraint of angular momentum conservation. While the reactants OH⁻ or H₂O are diamagnetic (DM), the O₂ product has a paramagnetic (PM) triplet ground state, requiring a change in spin configuration when being formed. This constraint has prompted interest in spin-selective catalysts as a means to facilitate OER. In this context, the roles of magnetism and chirality-induced spin selectivity (CISS) in promoting the OER reaction have recently been investigated through both theoretical and experimental studies. However, pinpointing the key principles and their relative contribution in mediating spin-enhancement remains a significant challenge. This roadmap offers a forward-looking perspective on current experimental trends and theoretical developments in spin-enhanced OER electrocatalysis and outlines strategic directions for integrating incisive experiments and operando approaches with computational modeling to disentangle key mechanisms. By providing a conceptual framework and identifying critical knowledge gaps, this perspective aims to guide researchers toward dedicated experimental and computational studies that will deepen the understanding of spin-induced OER enhancement and accelerate the development of next-generation catalysts.

Original language	English
Journal	Advanced energy materials
DOIs	https://doi.org/10.1002/aenm.202503556
Publication status	E-pub ahead of print/First online - 10 Oct 2025

Keywords

UT-Hybrid-D
CISS
experimental methodology
magnetic catalysts
polaron mediated OER
spin-enhanced OER
theoretical frameworks
chiral catalysts

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10.1002/aenm.202503556Licence: CC BY

Advanced Energy Materials - 2025 - van der Minne - Spin Matters A Multidisciplinary Roadmap to Understanding Spin EffectsFinal published version, 6.08 MBLicence: CC BY

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van der Minne, E., Vensaus, P., Ratovskii, V., Hariharan, S., Behrends, J., Franchini, C., Fransson, J., Dhesi, S. S., Gunkel, F., Gossing, F., Katsoukis, G., Kramm, U. I., Lingenfelder, M., Lan, Q., Kolen'ko, Y. V., Li, Y., Mohan, R. R., McCord, J., Ni, L., ... Baeumer, C. (2025). Spin Matters: A Multidisciplinary Roadmap to Understanding Spin Effects in Oxygen Evolution Reaction During Water Electrolysis. Advanced energy materials. Advance online publication. https://doi.org/10.1002/aenm.202503556

@article{48719ac04c074c82b18e4af06746732c,

title = "Spin Matters: A Multidisciplinary Roadmap to Understanding Spin Effects in Oxygen Evolution Reaction During Water Electrolysis",

abstract = "A central challenge in water electrolysis lies with the oxygen evolution reaction (OER) where the formation of molecular oxygen (O2) is hindered by the constraint of angular momentum conservation. While the reactants OH− or H2O are diamagnetic (DM), the O2 product has a paramagnetic (PM) triplet ground state, requiring a change in spin configuration when being formed. This constraint has prompted interest in spin-selective catalysts as a means to facilitate OER. In this context, the roles of magnetism and chirality-induced spin selectivity (CISS) in promoting the OER reaction have recently been investigated through both theoretical and experimental studies. However, pinpointing the key principles and their relative contribution in mediating spin-enhancement remains a significant challenge. This roadmap offers a forward-looking perspective on current experimental trends and theoretical developments in spin-enhanced OER electrocatalysis and outlines strategic directions for integrating incisive experiments and operando approaches with computational modeling to disentangle key mechanisms. By providing a conceptual framework and identifying critical knowledge gaps, this perspective aims to guide researchers toward dedicated experimental and computational studies that will deepen the understanding of spin-induced OER enhancement and accelerate the development of next-generation catalysts.",

keywords = "UT-Hybrid-D, CISS, experimental methodology, magnetic catalysts, polaron mediated OER, spin-enhanced OER, theoretical frameworks, chiral catalysts",

author = "\{van der Minne\}, Emma and Priscila Vensaus and Vadim Ratovskii and Seenivasan Hariharan and Jan Behrends and Cesare Franchini and Jonas Fransson and Dhesi, \{Sarnjeet S.\} and Felix Gunkel and Florian Gossing and Georgios Katsoukis and Kramm, \{Ulrike I.\} and Magal{\'i} Lingenfelder and Qianqian Lan and Kolen'ko, \{Yury V.\} and Yang Li and Mohan, \{Ramsundar Rani\} and Jeffrey McCord and Lingmei Ni and Eva Pavarini and Rossitza Pentcheva and Waldeck, \{David H.\} and Michael Verhage and Anke Yu and Xu, \{Zhichuan J.\} and Piero Torelli and Silvia Mauri and Narcis Avarvari and Anja Bieberle-H{\"u}tter and Christoph Baeumer",

note = "Publisher Copyright: {\textcopyright} 2025 The Author(s). Advanced Energy Materials published by Wiley-VCH GmbH.",

year = "2025",

month = oct,

day = "10",

doi = "10.1002/aenm.202503556",

language = "English",

journal = "Advanced energy materials",

issn = "1614-6832",

publisher = "Wiley",

}

van der Minne, E, Vensaus, P, Ratovskii, V, Hariharan, S, Behrends, J, Franchini, C, Fransson, J, Dhesi, SS, Gunkel, F, Gossing, F, Katsoukis, G, Kramm, UI, Lingenfelder, M, Lan, Q, Kolen'ko, YV, Li, Y, Mohan, RR, McCord, J, Ni, L, Pavarini, E, Pentcheva, R, Waldeck, DH, Verhage, M, Yu, A, Xu, ZJ, Torelli, P, Mauri, S, Avarvari, N, Bieberle-Hütter, A & Baeumer, C 2025, 'Spin Matters: A Multidisciplinary Roadmap to Understanding Spin Effects in Oxygen Evolution Reaction During Water Electrolysis', Advanced energy materials. https://doi.org/10.1002/aenm.202503556

TY - JOUR

T1 - Spin Matters

T2 - A Multidisciplinary Roadmap to Understanding Spin Effects in Oxygen Evolution Reaction During Water Electrolysis

AU - van der Minne, Emma

AU - Vensaus, Priscila

AU - Ratovskii, Vadim

AU - Hariharan, Seenivasan

AU - Behrends, Jan

AU - Franchini, Cesare

AU - Fransson, Jonas

AU - Dhesi, Sarnjeet S.

AU - Gunkel, Felix

AU - Gossing, Florian

AU - Katsoukis, Georgios

AU - Kramm, Ulrike I.

AU - Lingenfelder, Magalí

AU - Lan, Qianqian

AU - Kolen'ko, Yury V.

AU - Li, Yang

AU - Mohan, Ramsundar Rani

AU - McCord, Jeffrey

AU - Ni, Lingmei

AU - Pavarini, Eva

AU - Pentcheva, Rossitza

AU - Waldeck, David H.

AU - Verhage, Michael

AU - Yu, Anke

AU - Xu, Zhichuan J.

AU - Torelli, Piero

AU - Mauri, Silvia

AU - Avarvari, Narcis

AU - Bieberle-Hütter, Anja

AU - Baeumer, Christoph

PY - 2025/10/10

Y1 - 2025/10/10

N2 - A central challenge in water electrolysis lies with the oxygen evolution reaction (OER) where the formation of molecular oxygen (O2) is hindered by the constraint of angular momentum conservation. While the reactants OH− or H2O are diamagnetic (DM), the O2 product has a paramagnetic (PM) triplet ground state, requiring a change in spin configuration when being formed. This constraint has prompted interest in spin-selective catalysts as a means to facilitate OER. In this context, the roles of magnetism and chirality-induced spin selectivity (CISS) in promoting the OER reaction have recently been investigated through both theoretical and experimental studies. However, pinpointing the key principles and their relative contribution in mediating spin-enhancement remains a significant challenge. This roadmap offers a forward-looking perspective on current experimental trends and theoretical developments in spin-enhanced OER electrocatalysis and outlines strategic directions for integrating incisive experiments and operando approaches with computational modeling to disentangle key mechanisms. By providing a conceptual framework and identifying critical knowledge gaps, this perspective aims to guide researchers toward dedicated experimental and computational studies that will deepen the understanding of spin-induced OER enhancement and accelerate the development of next-generation catalysts.

AB - A central challenge in water electrolysis lies with the oxygen evolution reaction (OER) where the formation of molecular oxygen (O2) is hindered by the constraint of angular momentum conservation. While the reactants OH− or H2O are diamagnetic (DM), the O2 product has a paramagnetic (PM) triplet ground state, requiring a change in spin configuration when being formed. This constraint has prompted interest in spin-selective catalysts as a means to facilitate OER. In this context, the roles of magnetism and chirality-induced spin selectivity (CISS) in promoting the OER reaction have recently been investigated through both theoretical and experimental studies. However, pinpointing the key principles and their relative contribution in mediating spin-enhancement remains a significant challenge. This roadmap offers a forward-looking perspective on current experimental trends and theoretical developments in spin-enhanced OER electrocatalysis and outlines strategic directions for integrating incisive experiments and operando approaches with computational modeling to disentangle key mechanisms. By providing a conceptual framework and identifying critical knowledge gaps, this perspective aims to guide researchers toward dedicated experimental and computational studies that will deepen the understanding of spin-induced OER enhancement and accelerate the development of next-generation catalysts.

KW - UT-Hybrid-D

KW - CISS

KW - experimental methodology

KW - magnetic catalysts

KW - polaron mediated OER

KW - spin-enhanced OER

KW - theoretical frameworks

KW - chiral catalysts

UR - https://www.scopus.com/pages/publications/105018493180

U2 - 10.1002/aenm.202503556

DO - 10.1002/aenm.202503556

M3 - Review article

AN - SCOPUS:105018493180

SN - 1614-6832

JO - Advanced energy materials

JF - Advanced energy materials

ER -

Spin Matters: A Multidisciplinary Roadmap to Understanding Spin Effects in Oxygen Evolution Reaction During Water Electrolysis

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