Atomic force microscopy reveals thermally induced grain growth via shear-coupled migration

Jing Tang; Markus Kratzer; Lorenz Romaner; Jules M. Dake; Carl E. Krill III; Ronald Schnitzer; Christian Teichert; Marlene W. Kapp; Oliver Renk

doi:10.1080/21663831.2026.2628669

Atomic force microscopy reveals thermally induced grain growth via shear-coupled migration

Jing Tang
, Markus Kratzer
, Lorenz Romaner
, Jules M. Dake
, Carl E. Krill III
, Ronald Schnitzer
, Christian Teichert
, Marlene W. Kapp
, Oliver Renk

Universität Ulm
Erich-Schmid-Institut für Materialwissenschaft der Österreichischen Akademie der Wissenschaften

Publikation: Beitrag in Fachzeitschrift › Artikel › Forschung › Begutachtung

Abstract

Grain boundary (GB) migration is typically assumed to proceed by diffusive atomic events following curvature-driven flow. However, recent 4D (3D plus time) experiments and atomic-to-mesoscale simulations have shown that thermally induced grain growth in polycrystals deviates from this assumption. GB migration mediated by disconnections—producing both boundary translation and shear—may resolve this discrepancy, although such shear is usually restricted by surrounding grains. We directly demonstrate shear-coupled migration during grain growth in (Formula presented.) m-sized nickel by measuring surface displacements associated with GB migration using atomic force microscopy. Migrated GBs induced significant surface topography changes, clearly differing from grooves observed for stationary GBs.

Originalsprache	Englisch
Seiten (von - bis)	468-476
Seitenumfang	9
Fachzeitschrift	Materials Research Letters [Elektronische Ressource]
Jahrgang	2026
Ausgabenummer	Volume 14, Issue 4
DOIs	https://doi.org/10.1080/21663831.2026.2628669
Publikationsstatus	Veröffentlicht - 18 Feb. 2026

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Publisher Copyright:
© 2026 The Author(s). Published by Informa UK Limited, trading as Taylor & Francis Group.

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10.1080/21663831.2026.2628669

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abstract = "Grain boundary (GB) migration is typically assumed to proceed by diffusive atomic events following curvature-driven flow. However, recent 4D (3D plus time) experiments and atomic-to-mesoscale simulations have shown that thermally induced grain growth in polycrystals deviates from this assumption. GB migration mediated by disconnections—producing both boundary translation and shear—may resolve this discrepancy, although such shear is usually restricted by surrounding grains. We directly demonstrate shear-coupled migration during grain growth in (Formula presented.) m-sized nickel by measuring surface displacements associated with GB migration using atomic force microscopy. Migrated GBs induced significant surface topography changes, clearly differing from grooves observed for stationary GBs.",

keywords = "atomic force microscopy (AFM), Curvature driven grain growth, electron backscatter diffraction (EBSD), grain boundary disconnections, shear-coupled grain boundary migration",

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T1 - Atomic force microscopy reveals thermally induced grain growth via shear-coupled migration

AU - Tang, Jing

AU - Kratzer, Markus

AU - Romaner, Lorenz

AU - Dake, Jules M.

AU - Krill III, Carl E.

AU - Schnitzer, Ronald

AU - Teichert, Christian

AU - Kapp, Marlene W.

AU - Renk, Oliver

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AB - Grain boundary (GB) migration is typically assumed to proceed by diffusive atomic events following curvature-driven flow. However, recent 4D (3D plus time) experiments and atomic-to-mesoscale simulations have shown that thermally induced grain growth in polycrystals deviates from this assumption. GB migration mediated by disconnections—producing both boundary translation and shear—may resolve this discrepancy, although such shear is usually restricted by surrounding grains. We directly demonstrate shear-coupled migration during grain growth in (Formula presented.) m-sized nickel by measuring surface displacements associated with GB migration using atomic force microscopy. Migrated GBs induced significant surface topography changes, clearly differing from grooves observed for stationary GBs.

KW - atomic force microscopy (AFM)

KW - Curvature driven grain growth

KW - electron backscatter diffraction (EBSD)

KW - grain boundary disconnections

KW - shear-coupled grain boundary migration

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DO - 10.1080/21663831.2026.2628669

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JO - Materials Research Letters [Elektronische Ressource]

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