Atomistic aspects of fracture. Bitzek, E., Kermode, J. R., & Gumbsch, P. International Journal of Fracture, 191(1):13–30, Springer, February, 2015. ![Atomistic aspects of fracture [link]](https://bibbase.org/img/filetypes/link.svg "link")
Paper abstract bibtex Any fracture process ultimately involves the rupture of atomic bonds. Processes at the atomic scale therefore critically influence the toughness and overall fracture behavior of materials. Atomistic simulation methods including large-scale molecular dynamics simulations with classical potentials, density functional theory calculations and advanced concurrent multiscale methods have led to new insights e.g. on the role of bond trapping, dynamic effects, crack- microstructure interactions and chemical aspects on the fracture toughness and crack propagation patterns in metals and ceramics. This review focuses on atomistic aspects of fracture in crystalline materials where significant advances have been achieved over the last ten years and provides an outlook on future perspectives for atomistic modelling of fracture.
@article{wrap66441,
volume = {191},
number = {1},
month = {February},
author = {Erik Bitzek and James R. Kermode and Peter Gumbsch},
title = {Atomistic aspects of fracture},
publisher = {Springer},
year = {2015},
journal = {International Journal of Fracture},
pages = {13--30},
url = {https://wrap.warwick.ac.uk/66441/},
abstract = {Any fracture process ultimately involves the rupture of atomic bonds. Processes at the atomic scale therefore critically influence the toughness and overall fracture behavior of materials. Atomistic simulation methods including large-scale molecular dynamics simulations with classical potentials, density functional theory calculations and advanced concurrent multiscale methods have led to new insights e.g. on the role of bond trapping, dynamic effects, crack- microstructure interactions and chemical aspects on the fracture toughness and crack propagation patterns in metals and ceramics. This review focuses on atomistic aspects of fracture in crystalline materials where significant advances have been achieved over the last ten years and provides an outlook on future perspectives for atomistic modelling of fracture.}
}
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