Elisa Boatti scite author profile

Materials with engineered thermal expansion, capable of achieving targeted area/volume changes in response to variations in temperature, are important for a number of aerospace, optical, energy, and microelectronic applications. While most of the proposed structures with engineered coefficient of thermal expansion consist of bi-material 2D or 3D lattices, here it is shown that origami metamaterials also provide a platform for the design of systems with a wide range of thermal expansion coefficients. Experiments and simulations are combined to demonstrate that by tuning the geometrical parameters of the origami structure and the arrangement of plates and creases, an extremely broad range of thermal expansion coefficients can be obtained. Differently from all previously reported systems, the proposed structure is tunable in situ and nonporous.

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A three-dimensional finite-strain phenomenological model for shape-memory polymers: Formulation, numerical simulations, and comparison with experimental data

Boatti

Scalet

Auricchio

2016

International Journal of Plasticity

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Stimuli-induced bi-directional hydrogel unimorph actuators

Liu

Boatti

Bertoldi

et al. 2018

Extreme Mechanics Letters

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SMA Biomedical Applications

Auricchio¹,

Boatti²,

Conti³

2015

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Anisotropic Material Properties of Wild-Type and Tectb−/− Tectorial Membranes

Lemons

Sellon

Boatti

et al. 2019

Biophysical Journal

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The tectorial membrane (TM) is an extracellular matrix that is directly coupled with the mechanoelectrical receptors responsible for sensory transduction and amplification. As such, the TM is often hypothesized to play a key role in the remarkable sensory abilities of the mammalian cochlea. Genetic studies targeting TM proteins have shown that changes in TM structure dramatically affect cochlear function in mice. Precise information about the mechanical properties of the TMs of wild-type and mutant mice at audio frequencies is required to elucidate the role of the TM and to understand how these genetic mutations affect cochlear mechanics. In this study, images of isolated TM segments are used to determine both the radial and longitudinal motions of the TM in response to a harmonic radial excitation. The resulting longitudinally propagating radial displacement and highly spatially dependent longitudinal displacement are modeled using finite-element models that take into account the anisotropy and finite dimensions of TMs. An automated, least-square fitting algorithm is used to find the anisotropic material properties of wild-type and Tectb À/À mice at audio frequencies. Within the auditory frequency range, it is found that the TM is a highly viscoelastic and anisotropic structure with significantly higher stiffness in the direction of the collagen fibers. Although no decrease in the stiffness in the fiber direction is observed, the stiffness of the TM in shear and in the transverse direction is found to be significantly reduced in Tectb À/À mice. As a result, TMs of the mutant mice tend to be significantly more anisotropic within the frequency range examined in this study. The effects of the Tectb À/À mutation on the TM's anisotropic material properties may be responsible for the changes in cochlear tuning and sensitivity that have been previously reported for these mice.

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Gradient structures for the thermomechanics of shape-memory materials

Auricchio

Boatti

Reali

et al. 2016

Computer Methods in Applied Mechanics and Engineering

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Metamaterials: Origami Metamaterials for Tunable Thermal Expansion (Adv. Mater. 26/2017)

2017

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An origami metamaterial for tunable thermal expansion is described by Katia Bertoldi and co‐workers in article number https://doi.org/10.1002/adma.201700360. An extremely broad range of thermal‐expansion coefficients can be obtained by introducing bilayer plates and tuning the geometrical parameters of the origami structure. Differently from all previously reported systems, the proposed structure is tunable in situ and nonporous.

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SMA biomedical applications

Auricchio

Boatti

Conti

et al. 2021

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Elisa Boatti

Origami Metamaterials for Tunable Thermal Expansion

A three-dimensional finite-strain phenomenological model for shape-memory polymers: Formulation, numerical simulations, and comparison with experimental data

Stimuli-induced bi-directional hydrogel unimorph actuators

SMA Biomedical Applications

Anisotropic Material Properties of Wild-Type and Tectb−/− Tectorial Membranes

Gradient structures for the thermomechanics of shape-memory materials

Metamaterials: Origami Metamaterials for Tunable Thermal Expansion (Adv. Mater. 26/2017)

SMA biomedical applications

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