Print Email Facebook Twitter Curvature Induced by Deflection in Thick Meta-Plates Title Curvature Induced by Deflection in Thick Meta-Plates Author Mirzaali, Mohammad J. (TU Delft Biomaterials & Tissue Biomechanics) Ghorbani, Aref (Wageningen University & Research) Nakatani, Kenichi (Student TU Delft) Nouri Goushki, M. (TU Delft Biomaterials & Tissue Biomechanics) Tümer, N. (TU Delft Biomaterials & Tissue Biomechanics) Callens, S.J.P. (TU Delft Biomaterials & Tissue Biomechanics) Janbaz, S. (TU Delft Biomaterials & Tissue Biomechanics) Accardo, A. (TU Delft Micro and Nano Engineering) Bico, José (Sorbonne Université) Habibi, Mehdi (Wageningen University & Research) Zadpoor, A.A. (TU Delft Biomaterials & Tissue Biomechanics) Date 2021 Abstract The design of advanced functional devices often requires the use of intrinsically curved geometries that belong to the realm of non-Euclidean geometry and remain a challenge for traditional engineering approaches. Here, it is shown how the simple deflection of thick meta-plates based on hexagonal cellular mesostructures can be used to achieve a wide range of intrinsic (i.e., Gaussian) curvatures, including dome-like and saddle-like shapes. Depending on the unit cell structure, non-auxetic (i.e., positive Poisson ratio) or auxetic (i.e., negative Poisson ratio) plates can be obtained, leading to a negative or positive value of the Gaussian curvature upon bending, respectively. It is found that bending such meta-plates along their longitudinal direction induces a curvature along their transverse direction. Experimentally and numerically, it is shown how the amplitude of this induced curvature is related to the longitudinal bending and the geometry of the meta-plate. The approach proposed here constitutes a general route for the rational design of advanced functional devices with intrinsically curved geometries. To demonstrate the merits of this approach, a scaling relationship is presented, and its validity is demonstrated by applying it to 3D-printed microscale meta-plates. Several applications for adaptive optical devices with adjustable focal length and soft wearable robotics are presented. Subject 3D printingauxeticityfunctional materialsGaussian curvaturemechanical metamaterials To reference this document use: http://resolver.tudelft.nl/uuid:ea78f3ce-ae17-4fd3-8d9d-bf6c5e2189a6 DOI https://doi.org/10.1002/adma.202008082 ISSN 0935-9648 Source Advanced Materials, 33 (30) Part of collection Institutional Repository Document type journal article Rights © 2021 Mohammad J. Mirzaali, Aref Ghorbani, Kenichi Nakatani, M. Nouri Goushki, N. Tümer, S.J.P. Callens, S. Janbaz, A. Accardo, José Bico, Mehdi Habibi, A.A. Zadpoor Files PDF adma.202008082.pdf 7.5 MB Close viewer /islandora/object/uuid:ea78f3ce-ae17-4fd3-8d9d-bf6c5e2189a6/datastream/OBJ/view