Localized thermal emission from topological interfaces

M. Said Ergoktas; Ali Kecebas; Konstantinos Despotelis; Sina Soleymani; Gokhan Bakan; Askin Kocabas; Alessandro Principi; Stefan Rotter; Sahin K. Ozdemir; Coskun Kocabas

doi:10.1126/science.ado0534

Localized thermal emission from topological interfaces

M. Said Ergoktas, Ali Kecebas, Konstantinos Despotelis, Sina Soleymani, Gokhan Bakan, Askin Kocabas, Alessandro Principi, Stefan Rotter, Sahin K. Ozdemir, Coskun Kocabas

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28 Citations (SciVal)

Abstract

The control of thermal radiation by shaping its spatial and spectral emission characteristics plays a key role in many areas of science and engineering. Conventional approaches to tailoring thermal emission using metamaterials are hampered both by the limited spatial resolution of the required subwavelength material structures and by the materials' strong absorption in the infrared. In this work, we demonstrate an approach based on the concept of topology. By changing a single parameter of a multilayer coating, we were able to control the reflection topology of a surface, with the critical point of zero reflection being topologically protected. The boundaries between subcritical and supercritical spatial domains host topological interface states with near-unity thermal emissivity. These topological concepts enable unconventional manipulation of thermal light for applications in thermal management and thermal camouflage.

Original language	English
Pages (from-to)	1122-1126
Number of pages	5
Journal	Science (New York, N.Y.)
Volume	384
Issue number	6700
DOIs	https://doi.org/10.1126/science.ado0534
Publication status	Published - 7 Jun 2024

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title = "Localized thermal emission from topological interfaces",

abstract = "The control of thermal radiation by shaping its spatial and spectral emission characteristics plays a key role in many areas of science and engineering. Conventional approaches to tailoring thermal emission using metamaterials are hampered both by the limited spatial resolution of the required subwavelength material structures and by the materials' strong absorption in the infrared. In this work, we demonstrate an approach based on the concept of topology. By changing a single parameter of a multilayer coating, we were able to control the reflection topology of a surface, with the critical point of zero reflection being topologically protected. The boundaries between subcritical and supercritical spatial domains host topological interface states with near-unity thermal emissivity. These topological concepts enable unconventional manipulation of thermal light for applications in thermal management and thermal camouflage.",

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AU - Ergoktas, M. Said

AU - Kecebas, Ali

AU - Despotelis, Konstantinos

AU - Soleymani, Sina

AU - Bakan, Gokhan

AU - Kocabas, Askin

AU - Principi, Alessandro

AU - Rotter, Stefan

AU - Ozdemir, Sahin K.

AU - Kocabas, Coskun

PY - 2024/6/7

Y1 - 2024/6/7

N2 - The control of thermal radiation by shaping its spatial and spectral emission characteristics plays a key role in many areas of science and engineering. Conventional approaches to tailoring thermal emission using metamaterials are hampered both by the limited spatial resolution of the required subwavelength material structures and by the materials' strong absorption in the infrared. In this work, we demonstrate an approach based on the concept of topology. By changing a single parameter of a multilayer coating, we were able to control the reflection topology of a surface, with the critical point of zero reflection being topologically protected. The boundaries between subcritical and supercritical spatial domains host topological interface states with near-unity thermal emissivity. These topological concepts enable unconventional manipulation of thermal light for applications in thermal management and thermal camouflage.

AB - The control of thermal radiation by shaping its spatial and spectral emission characteristics plays a key role in many areas of science and engineering. Conventional approaches to tailoring thermal emission using metamaterials are hampered both by the limited spatial resolution of the required subwavelength material structures and by the materials' strong absorption in the infrared. In this work, we demonstrate an approach based on the concept of topology. By changing a single parameter of a multilayer coating, we were able to control the reflection topology of a surface, with the critical point of zero reflection being topologically protected. The boundaries between subcritical and supercritical spatial domains host topological interface states with near-unity thermal emissivity. These topological concepts enable unconventional manipulation of thermal light for applications in thermal management and thermal camouflage.

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JO - Science (New York, N.Y.)

JF - Science (New York, N.Y.)

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Localized thermal emission from topological interfaces

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