Nonreciprocal Heat Circulation Metadevices

Ju, Ran; Cao, Pei‐Chao; Wang, Dong; Qi, Minghong; Xu, Liujun; Yang, Shuihua; Qiu, Cheng‐Wei; Chen, Hongsheng; Li, Ying

doi:10.1002/adma.202309835

Cited by 7 publications

(2 citation statements)

References 55 publications

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“…78 This mechanism is also generalized to deal with steady-state and transient cases by the thermal scattering theory. 79 Wavelike diffusion unveils a fresh perspective on directional nonequilibrium energy and mass transfer, offering innovative strategies for manipulating diffusion processes.…”

Section: Distinct Applicationsmentioning

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: Distinct Applicationsmentioning

confidence: 99%

Spatiotemporal diffusion metamaterials: Theories and applications

Liu,

Xu,

Huang

2024

Applied Physics Letters

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“…Previous woks have contributed lots of efforts on the fluctuation modulation in thermal systems. Most of them were focusing on controlling the amplitudes of temperature fields, such as thermal rectification ( 12 , 13 ), with few exploration on the thermal phase. According to the Fourier’s equation for heat conduction, the onsite convective modulation in thermal diffusion is associated with the first-order derivative term of the temperature field, which determines the real part of the eigenfrequency that describes the phase fluctuation in heat transfer.…”

Section: Introductionmentioning

confidence: 99%

Observation of parity-time symmetry in diffusive systems

Cao,

Ju,

Wang

et al. 2024

Sci. Adv.

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Phase modulation has scarcely been mentioned in diffusive physical systems because the diffusion process does not carry the momentum like waves. Recently, non-Hermitian physics provides a unique perspective for understanding diffusion and shows prospects in thermal phase regulation, exemplified by the discovery of anti-parity-time (APT) symmetry in diffusive systems. However, precise control of thermal phase remains elusive hitherto and can hardly be realized, due to the phase oscillations. Here we construct the PT-symmetric diffusive systems to achieve the complete suppression of thermal phase oscillation. The real coupling of diffusive fields is readily established through a strong convective background, and the decay-rate detuning is enabled by thermal metamaterial design. We observe the phase transition of PT symmetry breaking with the symmetry-determined amplitude and phase regulation of coupled temperature fields. Our work shows the existence of PT symmetry in dissipative energy exchanges and provides unique approaches for harnessing the mass transfer of particles, wave dynamics in strongly scattering systems, and thermal conduction.

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