Stochastic or deterministic: Duality of fatigue behaviour of 3D-printed meta-biomaterials

The two deformation modes of meta-biomaterials during cyclic loading have been revealed: stochastic and deterministic strut failure processes. Biomimetic Voronoi structures with a range of strut thicknesses and number of cells per unit volume are printed. We show that when the strut thickness is 200...

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Bibliographic Details
Published in:Materials & design 2024-09, Vol.245, p.113296, Article 113296
Main Authors: Zhang, Jieming S., Liu, Huifang, Tang, Yuanbo T., Deng, Yun, Kuek, Nicole, Lui, Andrew, Grant, Patrick S., Alabort, Enrique, Reed, Roger C., Cocks, Alan C.F.
Format: Article
Language:English
Subjects:
3D-printing
Biomaterials
Fatigue
Finite element method
Meta-biomaterials
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Summary:The two deformation modes of meta-biomaterials during cyclic loading have been revealed: stochastic and deterministic strut failure processes. Biomimetic Voronoi structures with a range of strut thicknesses and number of cells per unit volume are printed. We show that when the strut thickness is 200 μm or above, the fatigue fracture process of the lattice is deterministic and the fatigue scatters are below 15%. As the strut is thinned to 150 μm, the local failures occur randomly within the structure, which may lead to a high fatigue scatter (>30%). The two distinct behaviours result from the processing limit of the laser powder bed fusion technique. We demonstrate that the fatigue scatter and the location of the failure process within the lattice are related to the probability that a cluster of unconnected struts larger than a critical value can exist within the lattice. Unlike solid parts, porosity hardly triggers any damage in metallic lattices during cyclic deformation. The discovery of the Janus-like failure process opens up our understanding of meta-biomaterials and defines the pathway towards the design of mechanically durable intricate implants. •Two distinct cyclic deformation modes of meta-biomaterials have been observed.•The fatigue response of meta-biomaterials is sensitive to the cluster size of unconnected struts.•Incorporating randomness in lattice design improves the tolerance to manufacturing defects under fatigue.
ISSN:0264-1275
DOI:10.1016/j.matdes.2024.113296