Magnetic microscopy for operando imaging of battery dynamics

Stefan Pollok; Mohamad Khoshkalam; Fardin Ghaffari-Tabrizi; Fran Kurnia; Danni Wang; Siqi Li; Dominik B. Bucher; Jennifer L.M. Rupp; Dennis V. Christensen

doi:10.1038/s41467-025-63409-y

Magnetic microscopy for operando imaging of battery dynamics

Stefan Pollok
, Mohamad Khoshkalam
, Fardin Ghaffari-Tabrizi
, Fran Kurnia
, Danni Wang
, Siqi Li
, Dominik B. Bucher
, Jennifer L.M. Rupp
, Dennis V. Christensen

Technical University of Denmark
Technical University of Munich
TUMint. Energy Research GmbH

Research output: Contribution to journal › Article › peer-review

5 Scopus citations

Abstract

Battery development pivots around understanding the complex processes governing battery operation and degradation. Most degradation pathways link structural and chemical inhomogeneities with strongly heterogeneous carrier transport at the nano- and microscale, which remains challenging to resolve with current operando imaging techniques. Here, we provide a data-driven perspective on using operando magnetic microscopy to examine the charge and discharge cycles in lithium and post-lithium batteries. Through quantitatively imaging ionic and electronic current distributions and probing the associated chemical reactions at the nanoscale, valuable insights into battery inhomogeneities and degradations can be gained. The approach facilitates spatially resolving heterogeneous redox reactions, buried current distributions, and mechanistic contributions to short-circuit endurance in batteries.

Original language	English
Article number	8303
Journal	Nature Communications
Volume	16
Issue number	1
DOIs	https://doi.org/10.1038/s41467-025-63409-y
State	Published - Dec 2025

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title = "Magnetic microscopy for operando imaging of battery dynamics",

abstract = "Battery development pivots around understanding the complex processes governing battery operation and degradation. Most degradation pathways link structural and chemical inhomogeneities with strongly heterogeneous carrier transport at the nano- and microscale, which remains challenging to resolve with current operando imaging techniques. Here, we provide a data-driven perspective on using operando magnetic microscopy to examine the charge and discharge cycles in lithium and post-lithium batteries. Through quantitatively imaging ionic and electronic current distributions and probing the associated chemical reactions at the nanoscale, valuable insights into battery inhomogeneities and degradations can be gained. The approach facilitates spatially resolving heterogeneous redox reactions, buried current distributions, and mechanistic contributions to short-circuit endurance in batteries.",

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AU - Pollok, Stefan

AU - Khoshkalam, Mohamad

AU - Ghaffari-Tabrizi, Fardin

AU - Kurnia, Fran

AU - Wang, Danni

AU - Li, Siqi

AU - Bucher, Dominik B.

AU - Rupp, Jennifer L.M.

AU - Christensen, Dennis V.

PY - 2025/12

Y1 - 2025/12

N2 - Battery development pivots around understanding the complex processes governing battery operation and degradation. Most degradation pathways link structural and chemical inhomogeneities with strongly heterogeneous carrier transport at the nano- and microscale, which remains challenging to resolve with current operando imaging techniques. Here, we provide a data-driven perspective on using operando magnetic microscopy to examine the charge and discharge cycles in lithium and post-lithium batteries. Through quantitatively imaging ionic and electronic current distributions and probing the associated chemical reactions at the nanoscale, valuable insights into battery inhomogeneities and degradations can be gained. The approach facilitates spatially resolving heterogeneous redox reactions, buried current distributions, and mechanistic contributions to short-circuit endurance in batteries.

AB - Battery development pivots around understanding the complex processes governing battery operation and degradation. Most degradation pathways link structural and chemical inhomogeneities with strongly heterogeneous carrier transport at the nano- and microscale, which remains challenging to resolve with current operando imaging techniques. Here, we provide a data-driven perspective on using operando magnetic microscopy to examine the charge and discharge cycles in lithium and post-lithium batteries. Through quantitatively imaging ionic and electronic current distributions and probing the associated chemical reactions at the nanoscale, valuable insights into battery inhomogeneities and degradations can be gained. The approach facilitates spatially resolving heterogeneous redox reactions, buried current distributions, and mechanistic contributions to short-circuit endurance in batteries.

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VL - 16

JO - Nature Communications

JF - Nature Communications

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Magnetic microscopy for operando imaging of battery dynamics

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