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Activation entropy of dislocation glide in body-centered cubic metals from atomistic simulations

Author

Listed:
  • Arnaud Allera

    (ASNR/PSN-RES/SEMIA/LSMA Centre d’études de Cadarache
    Institut Lumière Matière
    SRMP
    MATEIS)

  • Thomas D. Swinburne

    (CINaM
    University of Michigan)

  • Alexandra M. Goryaeva

    (SRMP)

  • Baptiste Bienvenu

    (SRMP
    Max Planck Institute for Sustainable Materials)

  • Fabienne Ribeiro

    (ASNR/PSN-RES/SEMIA/LSMA Centre d’études de Cadarache)

  • Michel Perez

    (MATEIS)

  • Mihai-Cosmin Marinica

    (SRMP)

  • David Rodney

    (Institut Lumière Matière)

Abstract

The activation entropy of dislocation glide, a key process controlling the strength of many metals, is often assumed to be constant or linked to enthalpy through the empirical Meyer-Neldel law-both of which are simplified approximations. In this study, we take a more direct approach by calculating the activation Gibbs energy for kink-pair nucleation on screw dislocations of two body-centered cubic metals, iron and tungsten. To ensure reliability, we develop machine learning interatomic potentials for both metals, carefully trained on dislocation data from density functional theory. Our findings reveal that dislocations undergo harmonic transitions between Peierls valleys, with an activation entropy that remains largely constant, regardless of temperature or applied stress. We use these results to parameterize a thermally-activated model of yield stress, which consistently matches experimental data in both iron and tungsten. Our work challenges recent studies using classical potentials, which report highly varying activation entropies, and suggests that simulations relying on classical potentials-widely used in materials modeling-could be significantly influenced by overestimated entropic effects.

Suggested Citation

  • Arnaud Allera & Thomas D. Swinburne & Alexandra M. Goryaeva & Baptiste Bienvenu & Fabienne Ribeiro & Michel Perez & Mihai-Cosmin Marinica & David Rodney, 2025. "Activation entropy of dislocation glide in body-centered cubic metals from atomistic simulations," Nature Communications, Nature, vol. 16(1), pages 1-8, December.
    • Handle: RePEc:nat:natcom:v:16:y:2025:i:1:d:10.1038_s41467-025-62390-w
    DOI: 10.1038/s41467-025-62390-w
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    References listed on IDEAS

    as
    1. Simon Gelin & Alexandre Champagne-Ruel & Normand Mousseau, 2020. "Enthalpy-entropy compensation of atomic diffusion originates from softening of low frequency phonons," Nature Communications, Nature, vol. 11(1), pages 1-7, December.
    2. Leo Zella & Jaeyun Moon & Takeshi Egami, 2024. "Ripples in the bottom of the potential energy landscape of metallic glass," Nature Communications, Nature, vol. 15(1), pages 1-7, December.
    3. Alexandra M. Goryaeva & Clovis Lapointe & Chendi Dai & Julien Dérès & Jean-Bernard Maillet & Mihai-Cosmin Marinica, 2020. "Reinforcing materials modelling by encoding the structures of defects in crystalline solids into distortion scores," Nature Communications, Nature, vol. 11(1), pages 1-14, December.
    4. Lucile Dezerald & David Rodney & Emmanuel Clouet & Lisa Ventelon & François Willaime, 2016. "Plastic anisotropy and dislocation trajectory in BCC metals," Nature Communications, Nature, vol. 7(1), pages 1-7, September.
    5. Luis A. Zepeda-Ruiz & Alexander Stukowski & Tomas Oppelstrup & Vasily V. Bulatov, 2017. "Probing the limits of metal plasticity with molecular dynamics simulations," Nature, Nature, vol. 550(7677), pages 492-495, October.
    6. Soumendu Bagchi & Danny Perez, 2025. "Anomalous entropy-driven kinetics of dislocation nucleation," Nature Communications, Nature, vol. 16(1), pages 1-9, December.
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