Thermal meta-device in analogue of zero-index photonics

Thermal meta-device in analogue of zero-index photonics

Inspired by the developments in photonic metamaterials, the concept of thermal metamaterials has promised new avenues for manipulating the flow of heat. In photonics, the existence of natural materials with both positive and negative permittivities has enabled the creation of metamaterials with a ve...

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Bibliographic Details
Published in:Nature materials Vol. 18; no. 1; pp. 48 - 54
Main Authors: Li, Ying, Zhu, Ke-Jia, Peng, Yu-Gui, Li, Wei, Yang, Tianzhi, Xu, He-Xiu, Chen, Hong, Zhu, Xue-Feng, Fan, Shanhui, Qiu, C.-W.
Format: Journal Article
Language:English
Published: London Nature Publishing Group UK 01-01-2019
Nature Publishing Group
Springer Nature - Nature Publishing Group
Subjects:
639/624/399/1015
639/766/25
639/766/530
Biomaterials
Chemistry
Chemistry and Materials Science
Condensed Matter Physics
Conductive heat transfer
Extreme environments
Fourier law
Heat conductivity
Heat transfer
Materials Science
Metamaterials
Nanotechnology
Optical and Electronic Materials
Parameters
Photonics
Physics
Thermal conductivity
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Summary:Inspired by the developments in photonic metamaterials, the concept of thermal metamaterials has promised new avenues for manipulating the flow of heat. In photonics, the existence of natural materials with both positive and negative permittivities has enabled the creation of metamaterials with a very wide range of effective parameters. In contrast, in conductive heat transfer, the available range of thermal conductivities in natural materials is far narrower, strongly restricting the effective parameters of thermal metamaterials and limiting possible applications in extreme environments. Here, we identify a rigorous correspondence between zero index in Maxwell’s equations and infinite thermal conductivity in Fourier’s law. We also propose a conductive system with an integrated convective element that creates an extreme effective thermal conductivity, and hence by correspondence a thermal analogue of photonic near-zero-index metamaterials, a class of metamaterials with crucial importance in controlling light. Synergizing the general properties of zero-index metamaterials and the specific diffusive nature of thermal conduction, we theoretically and experimentally demonstrate a thermal zero-index cloak. In contrast with conventional thermal cloaks, this meta-device can operate in a highly conductive background and the cloaked object preserves great sensitivity to external temperature changes. Our work demonstrates a thermal metamaterial which greatly enhances the capability for molding the flow of heat. In this type of thermal cloak, when a fluid circulates around the object of interest, the temperature perturbation is minimized as the effective thermal conductivity of the fluid becomes very high due to convective effects.
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content type line 23
FG02-07ER46426
USDOE Office of Science (SC)
ISSN:1476-1122
1476-4660
DOI:10.1038/s41563-018-0239-6