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Auteurs principaux: Xu, Xiandong, Erohin, Sergey V., Larionov, Konstantin V., Cheng, Q., Gan, Bin, Nasibulin, Albert, Sorokin, Pavel B.
Format: Preprint
Publié: 2025
Sujets:
Accès en ligne:https://arxiv.org/abs/2508.06929
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author Xu, Xiandong
Erohin, Sergey V.
Larionov, Konstantin V.
Cheng, Q.
Gan, Bin
Nasibulin, Albert
Sorokin, Pavel B.
author_facet Xu, Xiandong
Erohin, Sergey V.
Larionov, Konstantin V.
Cheng, Q.
Gan, Bin
Nasibulin, Albert
Sorokin, Pavel B.
contents Materials for extreme environments require high strength yet ductile to tolerate catastrophic damage. Face-centered cubic (FCC) metals are typically ductile under stress, but single-crystal FCC iridium exhibits intrinsically brittle, limiting its wider applications. Great efforts on theoretical studies have attributed this to non-planar dislocation cores or impurities, while direct experimental evidence has remained elusive. Here we report that high-density, sessile Frank dislocation loops with zero-net Burgers vectors are the primary cause of the brittleness, identified through atomic-resolution scanning transmission electron microscopy. Through first-principles calculations, supported by discrete dislocation dynamics simulations, we reveal that these loops form via an energetically favorable transformation from mixed perfect dislocations under stress, a process unique to iridium among other FCC metals. The immobile loops act as potent barriers, drastically increasing yield strength and work hardening by impeding dislocation glide and consuming mobile dislocations. These decisive results not only deepen the understanding of the iridium brittleness, but also describe the existence of a new embrittlement mechanism inherent to the FCC lattice and not previously described in the literature. The latter may enable novel routes for property tuning across a broad class of materials, which is of paramount importance to metallurgical technology
format Preprint
id arxiv_https___arxiv_org_abs_2508_06929
institution arXiv
publishDate 2025
record_format arxiv
spellingShingle Unveiling the Puzzle of Brittleness in Single Crystal Iridium
Xu, Xiandong
Erohin, Sergey V.
Larionov, Konstantin V.
Cheng, Q.
Gan, Bin
Nasibulin, Albert
Sorokin, Pavel B.
Materials Science
Materials for extreme environments require high strength yet ductile to tolerate catastrophic damage. Face-centered cubic (FCC) metals are typically ductile under stress, but single-crystal FCC iridium exhibits intrinsically brittle, limiting its wider applications. Great efforts on theoretical studies have attributed this to non-planar dislocation cores or impurities, while direct experimental evidence has remained elusive. Here we report that high-density, sessile Frank dislocation loops with zero-net Burgers vectors are the primary cause of the brittleness, identified through atomic-resolution scanning transmission electron microscopy. Through first-principles calculations, supported by discrete dislocation dynamics simulations, we reveal that these loops form via an energetically favorable transformation from mixed perfect dislocations under stress, a process unique to iridium among other FCC metals. The immobile loops act as potent barriers, drastically increasing yield strength and work hardening by impeding dislocation glide and consuming mobile dislocations. These decisive results not only deepen the understanding of the iridium brittleness, but also describe the existence of a new embrittlement mechanism inherent to the FCC lattice and not previously described in the literature. The latter may enable novel routes for property tuning across a broad class of materials, which is of paramount importance to metallurgical technology
title Unveiling the Puzzle of Brittleness in Single Crystal Iridium
topic Materials Science
url https://arxiv.org/abs/2508.06929