Abstract
AbstractThe prediction of atomistic fracture mechanisms in body-centred cubic (bcc) iron is essential for understanding its semi-brittle nature. Existing atomistic simulations of the crack-tip under mode-I loading based on empirical interatomic potentials yield contradicting predictions and artificial mechanisms. To enable fracture prediction with quantum accuracy, we develop a Gaussian approximation potential (GAP) using an active learning strategy by extending a density functional theory (DFT) database of ferromagnetic bcc iron. We apply the active learning algorithm and obtain a Fe GAP model with a converged model uncertainty over a broad range of stress intensity factors (SIFs) and for four crack systems. The learning efficiency of the approach is analysed, and the predicted critical SIFs are compared with Griffith and Rice theories. The simulations reveal that cleavage along the original crack plane is the atomistic fracture mechanism for {100} and {110} crack planes at T = 0 K, thus settling a long-standing issue. Our work also highlights the need for a multiscale approach to predicting fracture and intrinsic ductility, whereby finite temperature, finite loading rate effects and pre-existing defects (e.g., nanovoids, dislocations) should be taken explicitly into account.
Funder
University of Groningen FSE Startup Grant
Publisher
Springer Science and Business Media LLC
Subject
Computer Science Applications,Mechanics of Materials,General Materials Science,Modeling and Simulation
Reference53 articles.
1. Hartmaier, A. & Gumbsch, P. Scaling relations for crack-tip plasticity. Philos. Mag. A 82, 3187–3200 (2002).
2. Rice, J. R. Dislocation nucleation from a crack tip: an analysis based on the Peierls concept. J. Mech. Phys. Solids 40, 239–271 (1992).
3. Andric, P. & Curtin, W. A. Atomistic modeling of fracture. Model. Simul. Mater. Sci. Eng. 27, 013001 (2018).
4. Mak, E., Yin, B. & Curtin, W. A. A ductility criterion for bcc high entropy alloys. J. Mech. Phys. Solids 152, 104389 (2021).
5. Hribernik, M. L., Cleavage Oriented Iron Single Crystal Fracture Toughness PhD thesis (University of California, Santa Barbara, 2006).
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