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      Design of novel 3D auxetic structures based on S-shaped unit-cells

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      Smart Materials and Structures
      IOP Publishing

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          Abstract

          In this study, four novel three-dimensional (3D) warp and woof structures with negative Poisson’s ratio (NPR) were designed and assembled using the interlocking assembly method. The designed structures, including S-shaped auxetic unit-cells (UCs), exhibited NPR properties in two perpendicular planes. Because of the lower stress concentration of S-shaped than conventional re-entrant UCs, this UC was suggested for use in energy absorber structures. Furthermore, the mechanical behavior of the designed structures under quasi-static loading was simulated using the finite element method. In addition, two designed structures were fabricated using fused deposition modeling 3D printing technology and subjected to quasi-static compressive loading. The results of FE simulation and experimental work were verified and good agreement was found between them. Stress–strain diagrams, values of energy absorption ( W), specific energy absorption ( W s), and NPRs in two perpendicular planes were evaluated. The results showed that four designed auxetic structures had NPR in two perpendicular directions. In addition, stress concentration contours of the structures were investigated using FE simulation. Finally, considering the results of energy absorption and stress concentration for designed structures, the proposed structure to be utilized for energy-absorbing systems was introduced.

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          Auxetic mechanical metamaterials

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            Auxetic Materials: Functional Materials and Structures from Lateral Thinking!

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              Is Open Access

              Rationally designed meta-implants: a combination of auxetic and conventional meta-biomaterials

              Rationally designed meta-implants were found to create compression along both of their contact lines with the surrounding bone, thereby decreasing the chance of bone–implant interface failure (Hoffman's criterion) and wear particle-induced osteolysis, and improving bone ingrowth. Rationally designed meta-biomaterials present unprecedented combinations of mechanical, mass transport, and biological properties favorable for tissue regeneration. Here we introduce hybrid meta-biomaterials with rationally-distributed values of negative (auxetic) and positive Poisson's ratios, and use them to design meta-implants that unlike conventional implants do not retract from the bone under biomechanical loading. We rationally design and additively manufacture six different types of meta-biomaterials (three auxetic and three conventional), which then serve as the parent materials to six hybrid meta-biomaterials (with or without transitional regions). Both single and hybrid meta-biomaterials are mechanically tested to reveal their full-field strain distribution by digital image correlation. The best-performing hybrid meta-biomaterials are then selected for the design of meta-implants (hip stems), which are tested under simulated-implantation conditions. Full-field strain measurements clearly show that, under biomechanical loading, hybrid meta-implants press onto the bone on both the medial and lateral sides, thereby improving implant–bone contact and potentially implant longevity.
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                Author and article information

                Contributors
                Journal
                Smart Materials and Structures
                Smart Mater. Struct.
                IOP Publishing
                0964-1726
                1361-665X
                June 17 2022
                July 01 2022
                June 17 2022
                July 01 2022
                : 31
                : 7
                : 075024
                Article
                10.1088/1361-665X/ac7681
                a7aa3bbe-5695-4027-b46e-87bf08d3f43a
                © 2022

                https://iopscience.iop.org/page/copyright

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