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Mechanical Characterization and Inverse Design of Stochastic Architected Metamaterials Using Neural Operators (2311.13812v2)

Published 23 Nov 2023 in cond-mat.mtrl-sci and cs.AI

Abstract: Machine learning (ML) is emerging as a transformative tool for the design of architected materials, offering properties that far surpass those achievable through lab-based trial-and-error methods. However, a major challenge in current inverse design strategies is their reliance on extensive computational and/or experimental datasets, which becomes particularly problematic for designing micro-scale stochastic architected materials that exhibit nonlinear mechanical behaviors. Here, we introduce a new end-to-end scientific ML framework, leveraging deep neural operators (DeepONet), to directly learn the relationship between the complete microstructure and mechanical response of architected metamaterials from sparse but high-quality in situ experimental data. The approach facilitates the inverse design of structures tailored to specific nonlinear mechanical behaviors. Results obtained from spinodal microstructures, printed using two-photon lithography, reveal that the prediction error for mechanical responses is within a range of 5 - 10%. Our work underscores that by employing neural operators with advanced micro-mechanics experimental techniques, the design of complex micro-architected materials with desired properties becomes feasible, even in scenarios constrained by data scarcity. Our work marks a significant advancement in the field of materials-by-design, potentially heralding a new era in the discovery and development of next-generation metamaterials with unparalleled mechanical characteristics derived directly from experimental insights.

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References (67)
  1. Nanolattices: an emerging class of mechanical metamaterials, Advanced Materials 29 (2017) 1701850.
  2. Design, fabrication, and mechanics of 3d micro-nanolattices, Small 16 (2020) 1902842.
  3. Mechanical metamaterials and their engineering applications, Advanced Engineering Materials 21 (2019) 1800864.
  4. Ultralight metallic microlattices, Science 334 (2011) 962–965.
  5. Micro-architectured materials: past, present and future, Proceedings of the Royal Society A: Mathematical, Physical and Engineering Sciences 466 (2010) 2495–2516.
  6. Effective properties of the octet-truss lattice material, Journal of the Mechanics and Physics of Solids 49 (2001) 1747–1769.
  7. H. Jin, H. D. Espinosa, Mechanical metamaterials fabricated from self-assembly: A perspective, arXiv preprint arXiv:2311.06734 (2023).
  8. Strong, lightweight, and recoverable three-dimensional ceramic nanolattices, Science 345 (2014) 1322–1326.
  9. Approaching theoretical strength in glassy carbon nanolattices, Nature materials 15 (2016) 438–443.
  10. Lightweight, flaw-tolerant, and ultrastrong nanoarchitected carbon, Proceedings of the National Academy of Sciences 116 (2019) 6665–6672.
  11. Ultrastrong colloidal crystal metamaterials engineered with dna, Science Advances 9 (2023) eadj8103.
  12. Ultrahigh energy absorption multifunctional spinodal nanoarchitectures, Small 15 (2019) 1903834.
  13. Tailored buckling microlattices as reusable light-weight shock absorbers, Advanced Materials 28 (2016) 5865–5870.
  14. Nanoarchitected metal/ceramic interpenetrating phase composites, Science Advances 8 (2022) eabo3080.
  15. Supersonic impact resilience of nanoarchitected carbon, Nature Materials 20 (2021) 1491–1497.
  16. Folding at the microscale: Enabling multifunctional 3d origami-architected metamaterials, Small 16 (2020) 2002229.
  17. Origami with rotational symmetry: A review on their mechanics and design, Applied Mechanics Reviews 75 (2023) 050801.
  18. Origami tubes assembled into stiff, yet reconfigurable structures and metamaterials, Proceedings of the National Academy of Sciences 112 (2015) 12321–12326.
  19. Flexible mechanical metamaterials, Nature Reviews Materials 2 (2017) 1–11.
  20. Responsive materials architected in space and time, Nature Reviews Materials 7 (2022) 683–701.
  21. Merger of structure and material in nacre and bone–perspectives on de novo biomimetic materials, Progress in Materials Science 54 (2009) 1059–1100.
  22. Tablet-level origin of toughening in abalone shells and translation to synthetic composite materials, Nature communications 2 (2011) 173.
  23. F. Barthelat, H. Espinosa, An experimental investigation of deformation and fracture of nacre–mother of pearl, Experimental mechanics 47 (2007) 311–324.
  24. F. Barthelat, R. Rabiei, Toughness amplification in natural composites, Journal of the Mechanics and Physics of Solids 59 (2011) 829–840.
  25. Extreme mechanical resilience of self-assembled nanolabyrinthine materials, Proceedings of the National Academy of Sciences 117 (2020) 5686–5693.
  26. The mechanical response of cellular materials with spinodal topologies, Journal of the Mechanics and Physics of Solids 125 (2019) 401–419.
  27. Polyisoprene-polystyrene diblock copolymer phase diagram near the order-disorder transition, Macromolecules 28 (1995) 8796–8806.
  28. Dynamic fracture of a bicontinuously nanostructured copolymer: A deep-learning analysis of big-data-generating experiment, Journal of the Mechanics and Physics of Solids 164 (2022) 104898.
  29. Understanding the nanoscale deformation mechanisms of polyurea from in situ afm tensile experiments, in: Challenges in Mechanics of Time Dependent Materials, Mechanics of Biological Systems and Materials & Micro-and Nanomechanics, Volume 2: Proceedings of the 2021 Annual Conference & Exposition on Experimental and Applied Mechanics, Springer, 2022, pp. 45–51.
  30. Recent advances and applications of machine learning in experimental solid mechanics: A review, Applied Mechanics Reviews 75 (2023) 061001.
  31. Deep learning in mechanical metamaterials: From prediction and generation to inverse design, Advanced Materials (2023) 2302530.
  32. Inverse design of mechanical metamaterials with target nonlinear response via a neural accelerated evolution strategy, Advanced Materials 34 (2022) 2206238.
  33. Inverse-designed spinodoid metamaterials, npj Computational Materials 6 (2020) 73.
  34. Machine learning assisted design of shape-programmable 3d kirigami metamaterials, npj Computational Materials 8 (2022) 191.
  35. Designing complex architectured materials with generative adversarial networks, Science advances 6 (2020) eaaz4169.
  36. Deep learning-accelerated designs of tunable magneto-mechanical metamaterials, ACS Applied Materials & Interfaces 14 (2022) 33892–33902.
  37. Rapid inverse design of metamaterials based on prescribed mechanical behavior through machine learning, Nature Communications 14 (2023) 5765.
  38. C.-T. Chen, G. X. Gu, Generative deep neural networks for inverse materials design using backpropagation and active learning, Advanced Science 7 (2020) 1902607.
  39. Inverting the structure–property map of truss metamaterials by deep learning, Proceedings of the National Academy of Sciences 119 (2022) e2111505119.
  40. Machine learning for advanced additive manufacturing, Matter 3 (2020) 1541–1556.
  41. Machine learning in additive manufacturing: State-of-the-art and perspectives, Additive Manufacturing 36 (2020) 101538.
  42. Data-driven topology optimization of spinodoid metamaterials with seamlessly tunable anisotropy, Computer Methods in Applied Mechanics and Engineering 383 (2021) 113894.
  43. Optimally-tailored spinodal architected materials for multiscale design and manufacturing, Advanced Materials 34 (2022) 2109304.
  44. Autonomous experimentation systems for materials development: A community perspective, Matter 4 (2021) 2702–2726.
  45. A bayesian experimental autonomous researcher for mechanical design, Science advances 6 (2020) eaaz1708.
  46. Physics-informed machine learning, Nature Reviews Physics 3 (2021) 422–440.
  47. Learning nonlinear operators via deeponet based on the universal approximation theorem of operators, Nature machine intelligence 3 (2021) 218–229.
  48. A physics-informed variational deeponet for predicting crack path in quasi-brittle materials, Computer Methods in Applied Mechanics and Engineering 391 (2022) 114587.
  49. Interfacing finite elements with deep neural operators for fast multiscale modeling of mechanics problems, Computer methods in applied mechanics and engineering 402 (2022) 115027.
  50. Learning two-phase microstructure evolution using neural operators and autoencoder architectures, npj Computational Materials 8 (2022) 190.
  51. Operator learning for predicting multiscale bubble growth dynamics, The Journal of Chemical Physics 154 (2021).
  52. G2ϕitalic-ϕ\phiitalic_ϕnet: Relating genotype and biomechanical phenotype of tissues with deep learning, PLOS Computational Biology 18 (2022) e1010660.
  53. A generative modeling framework for inferring families of biomechanical constitutive laws in data-sparse regimes, arXiv preprint arXiv:2305.03184 (2023).
  54. Simulating progressive intramural damage leading to aortic dissection using deeponet: an operator–regression neural network, Journal of the Royal Society Interface 19 (2022) 20210670.
  55. J. H. Holland, Genetic algorithms, Scientific american 267 (1992) 66–73.
  56. Generative adversarial nets, Advances in neural information processing systems 27 (2014).
  57. M. Mirza, S. Osindero, Conditional generative adversarial nets, arXiv preprint arXiv:1411.1784 (2014).
  58. Achieving the theoretical limit of strength in shell-based carbon nanolattices, Proceedings of the National Academy of Sciences 119 (2022) e2119536119.
  59. Grain size gradient and length scale effect on mechanical behaviors of surface nanocrystalline metals, Materials Science and Engineering: A 725 (2018) 1–7.
  60. J. R. Greer, J. T. M. De Hosson, Plasticity in small-sized metallic systems: Intrinsic versus extrinsic size effect, Progress in Materials Science 56 (2011) 654–724.
  61. Intrinsic bauschinger effect and recoverable plasticity in pentatwinned silver nanowires tested in tension, Nano letters 15 (2015) 139–146.
  62. Nucleation-controlled distributed plasticity in penta-twinned silver nanowires, Small 8 (2012) 2986–2993.
  63. B-pinns: Bayesian physics-informed neural networks for forward and inverse pde problems with noisy data, Journal of Computational Physics 425 (2021) 109913.
  64. Uncertainty quantification in scientific machine learning: Methods, metrics, and comparisons, Journal of Computational Physics 477 (2023) 111902.
  65. X. Meng, G. E. Karniadakis, A composite neural network that learns from multi-fidelity data: Application to function approximation and inverse pde problems, Journal of Computational Physics 401 (2020) 109020.
  66. Extraction of mechanical properties of materials through deep learning from instrumented indentation, Proceedings of the National Academy of Sciences 117 (2020) 7052–7062.
  67. Multifidelity deep operator networks for data-driven and physics-informed problems, Journal of Computational Physics 493 (2023) 112462.
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