Mechanical Mode Engineering with Orthotropic Metamaterial Membranes

Conte, Gian Biagio; Vicarelli, Leonardo; Zanotto, Simone; Pitanti, Alessandro

doi:10.1002/admt.202200337

Cited by 4 publications

(1 citation statement)

References 53 publications

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“…If elastic metamaterials are used, C 66 can be equal to or greater than C 11 , possibly allowing elastic wave manipulation in an unprecedented way. Lee et al [143] proposed off-centered double-void-slit metamaterials, as shown in figure 10(a perforating slit-shaped void holes in isotropic materials, but other methods have also been proposed [145][146][147][148]. Research on breaking the symmetry of the elasticity tensor by using active elements has also been reported [149][150][151].…”

Section: Extreme Anisotropic Materials Propertiesmentioning

confidence: 99%

Elastic metamaterials for guided waves: from fundamentals to applications

Lee,

Kim

2023

Smart Mater. Struct.

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Guided waves, elastic waves propagating through bounded structures, play a pivotal role in various applications, including ultrasonic non-destructive testing and structural health monitoring. Recently, elastic metamaterials artificially engineered to exhibit physical properties not typically seen in nature have emerged as a ground-breaking approach, heralding a new era in guided wave-based technologies. These metamaterials offer innovative solutions to overcome the inherent constraints of traditional guided wave-based technology. This paper comprehensively reviews elastic metamaterials from their fundamental principles to diverse applications, focusing on their transformative impact in guided wave manipulation.

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Section: Extreme Anisotropic Materials Propertiesmentioning

confidence: 99%

Elastic metamaterials for guided waves: from fundamentals to applications

Lee,

Kim

2023

Smart Mater. Struct.

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Highly dispersive multiplexed micromechanical device array for spatially resolved sensing and actuation

Gregorat,

Cautero,

Vicarelli

et al. 2024

Microsyst Nanoeng

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The powerful resource of parallelizing simple devices for realizing and enhancing complex operations comes with the drawback of multiple connections for addressing and controlling the individual elements. Here we report on a technological platform where several mechanical resonators can be individually probed and electrically actuated by using dispersive multiplexing within a single electrical channel. We demonstrate room temperature control of the individual device vibrational motion and spatially-resolved readouts. As the single elements have proven to be excellent bolometers and individual nodes for reservoir computing, our platform can be directly employed for single-channel addressing of multiple devices, with immediate applications for far-infrared cameras, spatial light modulators and recurrent neural networks operating at room temperature.

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Mechanical investigations of free-standing SiN membranes patterned with one-dimensional photonic crystal structures

Darki

Nielsen

Nygaard

et al. 2022

Journal of Applied Physics

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A detailed investigation of the structural and vibrational properties of various prestressed silicon nitride membranes patterned with one-dimensional photonic crystal structures is presented. The tensile stress related deformation of the structure in the vicinity of the patterned area is determined by atomic force microscopy scans, while the resonance frequencies and quality factors of the out-of-plane membrane vibrations are measured using optical interferometry. We show that these noninvasive measurements, combined with the results of finite element simulations, provide accurate information on the tensile stress, the elasticity modulus, and the density of these nanostructured thin films. The obtained results are interesting in two ways: first, they show that such highly reflective thin membranes already exploited in various photonics applications possess high-mechanical quality, which also makes them attractive for optomechanics and sensing applications. Second, they represent a nondestructive method to determine key material parameters, which can be applicable to a broad range of fragile nanostructured thin films.

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Mechanical Mode Engineering with Orthotropic Metamaterial Membranes

Cited by 4 publications

References 53 publications

Elastic metamaterials for guided waves: from fundamentals to applications

Elastic metamaterials for guided waves: from fundamentals to applications

Highly dispersive multiplexed micromechanical device array for spatially resolved sensing and actuation

Mechanical investigations of free-standing SiN membranes patterned with one-dimensional photonic crystal structures

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