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Autori principali: Zhang, Yue, Li, Longnan, Dai, Junyan, Zhang, Xiaowen, Zhou, Qunyan, Yi, Naiqin, Jian, Ruizhe, Zhu, Fei, Li, Xiaopeng, Sun, Mengke, Wu, Jiazheng, Li, Xinfeng, Kong, Xiangtong, Liu, Ziai, Li, Yinwei, Cheng, Qiang, Zhu, Yiming, Cui, Tie Jun, Li, Wei
Natura: Preprint
Pubblicazione: 2025
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Accesso online:https://arxiv.org/abs/2510.16372
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author Zhang, Yue
Li, Longnan
Dai, Junyan
Zhang, Xiaowen
Zhou, Qunyan
Yi, Naiqin
Jian, Ruizhe
Zhu, Fei
Li, Xiaopeng
Sun, Mengke
Wu, Jiazheng
Li, Xinfeng
Kong, Xiangtong
Liu, Ziai
Li, Yinwei
Cheng, Qiang
Zhu, Yiming
Cui, Tie Jun
Li, Wei
author_facet Zhang, Yue
Li, Longnan
Dai, Junyan
Zhang, Xiaowen
Zhou, Qunyan
Yi, Naiqin
Jian, Ruizhe
Zhu, Fei
Li, Xiaopeng
Sun, Mengke
Wu, Jiazheng
Li, Xinfeng
Kong, Xiangtong
Liu, Ziai
Li, Yinwei
Cheng, Qiang
Zhu, Yiming
Cui, Tie Jun
Li, Wei
contents Low emissivity (low-e) materials are crucial for conserving thermal energy in buildings, cold chain logistics and transportation by minimizing unwanted radiative heat loss or gain. However, their metallic nature intrinsically causes severe longwave attenuation, hindering their broad applications. Here, we introduce, for the first time, an all-dielectric longwave-transparent low-emissivity material (LLM) with ultra-broadband, high transmittance spanning 9 orders of magnitude, from terahertz to kilohertz frequencies. This meter-scale LLM not only achieves energy savings of up to 41.1% over commercial white paint and 10.2% over traditional low-e materials, but also unlocks various fundamentally new capabilities including high-speed wireless communication in energy-efficient buildings, wireless energy transfer with radiative thermal insulation, as well as non-invasive terahertz security screening and radio frequency identification in cold chain logistics. Our approach represents a new photonic solution towards carbon neutrality and smart city development, paving the way for a more sustainable and interconnected future.
format Preprint
id arxiv_https___arxiv_org_abs_2510_16372
institution arXiv
publishDate 2025
record_format arxiv
spellingShingle Longwave-transparent low-emissivity material
Zhang, Yue
Li, Longnan
Dai, Junyan
Zhang, Xiaowen
Zhou, Qunyan
Yi, Naiqin
Jian, Ruizhe
Zhu, Fei
Li, Xiaopeng
Sun, Mengke
Wu, Jiazheng
Li, Xinfeng
Kong, Xiangtong
Liu, Ziai
Li, Yinwei
Cheng, Qiang
Zhu, Yiming
Cui, Tie Jun
Li, Wei
Optics
Low emissivity (low-e) materials are crucial for conserving thermal energy in buildings, cold chain logistics and transportation by minimizing unwanted radiative heat loss or gain. However, their metallic nature intrinsically causes severe longwave attenuation, hindering their broad applications. Here, we introduce, for the first time, an all-dielectric longwave-transparent low-emissivity material (LLM) with ultra-broadband, high transmittance spanning 9 orders of magnitude, from terahertz to kilohertz frequencies. This meter-scale LLM not only achieves energy savings of up to 41.1% over commercial white paint and 10.2% over traditional low-e materials, but also unlocks various fundamentally new capabilities including high-speed wireless communication in energy-efficient buildings, wireless energy transfer with radiative thermal insulation, as well as non-invasive terahertz security screening and radio frequency identification in cold chain logistics. Our approach represents a new photonic solution towards carbon neutrality and smart city development, paving the way for a more sustainable and interconnected future.
title Longwave-transparent low-emissivity material
topic Optics
url https://arxiv.org/abs/2510.16372