Abstract
Spinodal metamaterials, with architectures inspired by natural phase-separation processes, have presented a significant alternative to periodic and symmetric morphologies when designing mechanical metamaterials with extreme performance. While their elastic mechanical properties have been systematically determined, their large-deformation, nonlinear responses have been challenging to predict and design, in part due to limited data sets and the need for complex nonlinear simulations. This work presents a novel physics-enhanced machine learning (ML) and optimization framework tailored to address the challenges of designing intricate spinodal metamaterials with customized mechanical properties in large-deformation scenarios where computational modeling is restrictive and experimental data is sparse. By utilizing large-deformation experimental data directly, this approach facilitates the inverse design of spinodal structures with precise finite-strain mechanical responses. The framework sheds light on instability-induced pattern formation in spinodal metamaterials—observed experimentally and in selected nonlinear simulations—leveraging physics-based inductive biases in the form of nonconvex energetic potentials. Altogether, this combined ML, experimental, and computational effort provides a route for efficient and accurate design of complex spinodal metamaterials for large-deformation scenarios where energy absorption and prediction of nonlinear failure mechanisms is essential.
Original language | English |
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Article number | 102274 |
Number of pages | 12 |
Journal | Extreme Mechanics Letters |
Volume | 74 |
DOIs | |
Publication status | Published - 2025 |
Keywords
- In situ characterization
- Inverse design
- Machine learning
- Nonlinear properties
- Spinodal metamaterials
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Data and Code underlying publication: Experiment-informed finite-strain inverse design of spinodal metamaterials
Thakolkaran, P. (Creator), Kumar, S. (Creator), Espinal, M. (Creator), Dhulipala, S. (Creator) & Portela, C. M. (Creator), TU Delft - 4TU.ResearchData, 30 Dec 2024
DOI: 10.4121/bdc2b8d2-d000-4f56-ab0e-e64a147220fd
Dataset/Software: Software