Litcius/Paper detail

All‐Solid‐State Transparent Variable Infrared Emissivity Devices for Multi‐Mode Smart Windows

Hulin Zhang, Xiang Zhang, Wenhai Sun, Mingjun Chen, Yingjun Xiao, Zhenmin Ding, Dukang Yan, Jian-Bo Deng, Zitong Li, Jiupeng Zhao, Yao Li

2023Advanced Functional Materials47 citationsDOIOpen Access PDF

Abstract

Abstract Smart windows that incorporate photothermal modulators (PMs) can independently regulate solar transmittance and infrared (IR) emissivity to improve building comfort and reduce energy consumption. Herein, a novel all‐solid‐state variable IR emissivity device (VED) is first designed and fabricated with a high visible irradiation transmittance ( T ′ vis = 0.79) and solar irradiation transmittance ( T ′ sol = 0.75) using an ITO/SiO 2 /ITO Fabry–Perot cavity structure. The VED exhibits different IR emissivity (ɛ) values at positive (ɛ P = 0.80) and negative (ɛ N = 0.38) bias, allowing for dynamic regulation of radiation by controlling the electrical conductivity of the indium tin oxide (ITO) layer. Furthermore, an all‐solid‐state PM with a structure of ITO/SiO 2 /ITO/Glass/ITO/NiO/ZrO 2 /Li/WO 3 /ITO, which is capable of independently regulating solar transmittance (Δ T' sol = 0.31) and IR emissivity (Δɛ 2.5–25 µm = 0.42), is fabricated. The multi‐mode smart window incorporating PMs can achieve “bright,” “dark,” “warm,” and “cool” modes, making them suitable for deployment in diverse climate zones. The innovative smart window holds a massive potential for use in reducing building energy consumption.

Topics & Concepts

Materials scienceTransmittanceEmissivityInfrared windowOptoelectronicsInfraredIndium tin oxideLow emissivityOpticsNanotechnologyLayer (electronics)PhysicsThermal Radiation and Cooling TechnologiesTransition Metal Oxide NanomaterialsUrban Heat Island Mitigation