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Auxetic metamaterials are commonly thought to exhibit favorable mechanical properties, notably high-energy absorption. Here we investigate disordered metamaterials obtained from random beam networks by optimizing simultaneously auxeticity and the energy absorbed before fracture. By giving different weights to these optimization targets, we demonstrate that the optimal configurations are connected along a Pareto front where high auxeticity implies comparatively low-energy absorption and vice versa. We study the mechanical properties of the resulting metamaterials and characterize the different deformation modes obtained for distinct optimization targets. The simulation and optimization results are validated by comparison with the deformation behavior of additively manufactured samples. Our work provides an illustration of the potentials and limitations of multiobjective optimization in the design of disordered mechanical metamaterials.

Fracture toughness and auxeticity in disordered metamaterials / H. Holey, A.L.H.S. Detry, S. Bonfanti, R. Guerra, A.D.S. Parmar, J. Fiocchi, A. Tuissi, M. Zaiser, S. Zapperi. - In: PHYSICAL REVIEW APPLIED. - ISSN 2331-7019. - 25:2(2026), pp. 024075.1-024075.14. [10.1103/r66g-hyxx]

Fracture toughness and auxeticity in disordered metamaterials

H. Holey
Primo
;A.L.H.S. Detry
Secondo
;S. Bonfanti;R. Guerra;S. Zapperi
Ultimo
2026

Abstract

Auxetic metamaterials are commonly thought to exhibit favorable mechanical properties, notably high-energy absorption. Here we investigate disordered metamaterials obtained from random beam networks by optimizing simultaneously auxeticity and the energy absorbed before fracture. By giving different weights to these optimization targets, we demonstrate that the optimal configurations are connected along a Pareto front where high auxeticity implies comparatively low-energy absorption and vice versa. We study the mechanical properties of the resulting metamaterials and characterize the different deformation modes obtained for distinct optimization targets. The simulation and optimization results are validated by comparison with the deformation behavior of additively manufactured samples. Our work provides an illustration of the potentials and limitations of multiobjective optimization in the design of disordered mechanical metamaterials.
Settore PHYS-04/A - Fisica teorica della materia, modelli, metodi matematici e applicazioni
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   ARCHIBIOFOAM
   EUROPEAN COMMISSION
   101161052

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   METACTOR
   MINISTERO DELL'UNIVERSITA' E DELLA RICERCA
   2022NZXE4M_001

   Tribo-Electricity: a New Route for Tribology (TRIEL)
   TRIEL
   MINISTERO DELL'UNIVERSITA' E DELLA RICERCA
   2022EY22PZ_001

   Centre of Excellence in Multifunctional Materials for Industrial and Medical Applications
   NOMATEN
   European Commission
   Horizon 2020 Framework Programme - Coordination and support action
   857470
2026
24-feb-2026
PHYSICAL REVIEW APPLIED
Article (author)
01 - Articolo su periodico
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Utilizza questo identificativo per citare o creare un link a questo documento: https://hdl.handle.net/2434/1245575
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