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Boron triggers grain boundary structural transformation in steel

Xuyang Zhou (), Sourabh Kumar, Siyuan Zhang, Xinren Chen, Baptiste Gault, Gerhard Dehm, Tilmann Hickel () and Dierk Raabe ()
Additional contact information
Xuyang Zhou: Max-Planck-Institut for Sustainable Materials
Sourabh Kumar: Federal Institute for Materials Research and Testing (BAM)
Siyuan Zhang: Max-Planck-Institut for Sustainable Materials
Xinren Chen: Max-Planck-Institut for Sustainable Materials
Baptiste Gault: Max-Planck-Institut for Sustainable Materials
Gerhard Dehm: Max-Planck-Institut for Sustainable Materials
Tilmann Hickel: Max-Planck-Institut for Sustainable Materials
Dierk Raabe: Max-Planck-Institut for Sustainable Materials

Nature Communications, 2025, vol. 16, issue 1, 1-14

Abstract: Abstract Boron enhances the hardenability of low-alloyed steel and reduces embrittlement at low temperatures, at parts-per-million concentration levels. Its effectiveness arises from segregation to grain boundaries (GBs)-planar defects between crystals-yet atomic-scale evidence remains limited. We addressed this gap by synthesizing GBs with controllable geometry and orientation, enabling reproducible comparison with and without boron segregation. Differential phase-contrast imaging directly reveals boron at iron GBs, and in-situ TEM heating (20 °C to 800 °C) allows us to track the dynamic evolution of GB structures. We found that boron segregation induces local structural changes and triggers GB phase transformations, as corroborated by calculated GB defect phase diagrams spanning broad ranges of carbon and boron content. Our findings not only bridge a gap in understanding the interplay between GB structure and chemistry but also lay the groundwork for targeted design and passivation strategies in steel, potentially transforming its resistance to hydrogen embrittlement, corrosion, and mechanical failure.

Date: 2025
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DOI: 10.1038/s41467-025-62264-1

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