Nonreciprocal elasticity and the realization of static and dynamic nonreciprocity

Shaat, Mohamed

doi:10.1038/s41598-020-77949-4

Cited by 11 publications

(4 citation statements)

References 58 publications

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“…One simple example is the realization of nonreciprocal transmission of the displacement field through the fabrication of silicon rubber into a fishbone-structured metamaterial ( 10 ). However, mechanical nonreciprocity has so far mainly been realized through the complicated design of active robotics ( 15 , 16 ) or metamaterial frameworks ( 17 , 18 ). Even the most advanced systems still rely on the shaping and connection of reciprocal materials, which limits the design freedom and practical applications of such systems.…”

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confidence: 99%

Mechanical nonreciprocity in a uniform composite material

Wang

et al. 2023

Science

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Mechanical nonreciprocity, or the asymmetric transmission of mechanical quantities between two points in space, is crucial for developing systems that can guide, damp, and control mechanical energy. We report a uniform composite hydrogel that displays substantial mechanical nonreciprocity, owing to direction-dependent buckling of embedded nanofillers. This material exhibits an elastic modulus more than 60 times higher when sheared in one direction compared with the opposite direction. Consequently, it can transform symmetric vibrations into asymmetric ones that are applicable for mass transport and energy harvest. Furthermore, it exhibits an asymmetric deformation when subjected to local interactions, which can induce directional motion of various objects, including macroscopic objects and even small living creatures. This material could promote the development of nonreciprocal systems for practical applications such as energy conversion and biological manipulation.

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confidence: 99%

Mechanical nonreciprocity in a uniform composite material

Wang

et al. 2023

Science

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“…Recently, there has been a growing interest in breaking the symmetry of signal transmission in both temporal and spatial dimensions to induce nonreciprocal behaviors, mainly in dynamic systems involving electromagnetic (3)(4)(5), acoustic (6)(7)(8), and mechanical (9-13) wave propagation. Static nonreciprocity introduces a unique ability to manipulate mechanical signals and energy without requiring active time-modulated components (14)(15)(16)(17)(18). For example, Coulais et al (14) broke the Maxwell-Betti reciprocity theorem with a fishbone metamaterial, revealing static shear nonreciprocity.…”

Section: Introductionmentioning

confidence: 99%

Programmable nonreciprocal Poynting effect enabled by lattice metamaterials

Dong,

Zhou,

Wang

2024

Sci. Adv.

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Shear nonreciprocity, implying unequal shear forces in opposite shear directions, can be achieved by arranging structures asymmetrically. However, the nonreciprocal Poynting effect, i.e., unequal normal stresses induced by the same shear displacements to the left and right, has not been fully explored. We discover the nonreciprocal Poynting effect using a generalized directional truss model. Inspired by this discovery, the cylindrical lattice metamaterials constructed from antisymmetric curled microstructures are used as a case study to generate the nonreciprocal Poynting effect. We develop a design framework that integrates digital generation, finite deformation theory, finite element modeling, and three-dimensional printing to program the nonreciprocal Poynting effect. Applications such as bionic Poynting effect matching, wave energy converter, and unidirectional motion limitation are demonstrated. This framework allows the one-to-one mapping between the torque and normal forces, paving the way for designing soft devices with precise force transmission capabilities.

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“…The macroscopic response of the metamaterial is assessed based on an effective medium description without explicitly taking into account internal degrees of freedom, inhomogeneities or other components that exist within the structure. A wide range of mechanical behavior is realized across the different architectures for example, negative effective elastic constants [4][5][6][7], multistable structures [8][9][10][11][12][13][14], reversal of Saint Venant end effects [10], static non-reciprocity [15,16] and other behaviors [17,18].…”

Section: Introductionmentioning

confidence: 99%