Abstract
AbstractUnderstanding fracture is critical to the design of resilient nanomaterials. Molecular dynamics offers a way to study fracture at an atomistic level, but is computationally expensive with limitations of scalability. In this work, we build upon machine-learning approaches for predicting nanoscopic fracture mechanisms including crack instabilities and branching as a function of crystal orientation. We focus on a particular technologically relevant material system, graphene, and apply a deep learning method to the study of such nanomaterials and explore the parameter space necessary for calibrating machine-learning predictions to meaningful results. Our results validate the ability of deep learning methods to quantitatively capture graphene fracture behavior, including its fractal dimension as a function of crystal orientation, and provide promise toward the wider application of deep learning to materials design, opening the potential for other 2D materials.
Publisher
Springer Science and Business Media LLC
Subject
Mechanical Engineering,Mechanics of Materials,Condensed Matter Physics,General Materials Science,General Chemistry
Reference38 articles.
1. Buehler, M. J. Atomistic Modeling of Materials Failure, https://doi.org/10.1007/978-0-387-76426-9 (Springer, 2008).
2. Jung, G. S. et al. Interlocking friction governs the mechanical fracture of bilayer MoS2. ACS Nano 12, 3600–3608 (2018).
3. Jung, G. S. et al. Anisotropic fracture dynamics due to local lattice distortions. ACS Nano 13, 5693–5702 (2019).
4. Wang, S. S. et al. Atomically sharp crack tips in monolayer MoS2 and their enhanced toughness by vacancy defects. ACS Nano 10, 9831–9839 (2016).
5. Peng, G. C. Y. et al. Multiscale modeling meets machine learning: what can we learn? Arch. Comput. Methods Eng. 1, 3 (2020).
Cited by
54 articles.
订阅此论文施引文献
订阅此论文施引文献,注册后可以免费订阅5篇论文的施引文献,订阅后可以查看论文全部施引文献