Active nonreciprocal metamaterial using a spatiotemporal modulation control strategy

Zhou, Han; Baz, A.

doi:10.1063/5.0100804

Cited by 5 publications

(1 citation statement)

References 41 publications

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“…[25][26][27][28] This new class of materials serves as a temporal extension of traditional metamaterials and opens a new avenue to manipulating physical fields with dynamic structures. Exciting developments in electromagnetic and acoustic systems have been achieved, such as nonreciprocal [29][30][31][32][33] and topological 34 transport. However, adding the temporal dimension to previous diffusion metamaterials is particularly challenging due to different governing equations and parameter properties.…”

Section: Introductionmentioning

confidence: 99%

Spatiotemporal diffusion metamaterials: Theories and applications

Liu,

Xu,

Huang

2024

Applied Physics Letters

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Diffusion metamaterials with artificial spatial structures have significant potential in controlling energy and mass transfer. Those static structures may lead to functionality and tunability constraints, impeding the application scope of diffusion metamaterials. Dynamic structures, adding the temporal dimension, have recently provided a new possibility for electric charge and heat diffusion regulation. This perspective introduces the fundamental theories and practical constructions of spatiotemporal diffusion metamaterials for achieving nonreciprocal, topological, or tunable properties. Compared with traditional static design, spatiotemporal modulation is promising to manipulate diffusion processes dynamically, with applications of real-time thermal coding and programming. Existing spatiotemporal diffusion explorations are primarily at macroscopic systems, and we may envision extending these results to microscale and other physical domains like thermal radiation and mass diffusion shortly.

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Section: Introductionmentioning

confidence: 99%

Spatiotemporal diffusion metamaterials: Theories and applications

Liu,

Xu,

Huang

2024

Applied Physics Letters

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Nonreciprocal wave propagation in a time-space modulated metasurface using the modified plane wave expansion method

Kargozarfard,

Sedighi,

Yaghootian

et al. 2024

Thin-Walled Structures

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Underwater Acoustic Non-Reciprocal Manipulation Based on Dynamic-Modulation Structures

Wen,

Yuan,

Huang

et al. 2024

Journal of Applied Mechanics

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Underwater acoustic non-reciprocal transmission via dynamic-modulation structures with time-varying mass and stiffness is studied. The model system consists of spatiotemporally modulated discrete lattices immersed in the water background. Based on the transfer matrix method, an analytic model for the coupled continuum-discrete system is developed to calculate acoustic scattering responses in the frequency domain. Finite-difference time-domain computation is conducted for the coupled system to verify the theoretical model. Results show that acoustic non-reciprocal transmission in opposite directions appears at frequencies where there are asymmetric bandgaps in dispersion diagrams. Asymmetric transmission can be enhanced in magnitude by engineering the modulating amplitudes of time-varying parameters or increasing the number of lattice elements, while the frequency bandwidth can be broadened by cascading structural elements with different modulating frequencies due to the gap-combining effect. The model may find potential applications in underwater acoustic isolation and sonar communication.

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Active nonreciprocal metamaterial using a spatiotemporal modulation control strategy

Cited by 5 publications

References 41 publications

Spatiotemporal diffusion metamaterials: Theories and applications

Spatiotemporal diffusion metamaterials: Theories and applications

Nonreciprocal wave propagation in a time-space modulated metasurface using the modified plane wave expansion method

Underwater Acoustic Non-Reciprocal Manipulation Based on Dynamic-Modulation Structures

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