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Structural Engineering in Sn-Doped WOsub.3 Multi-Phase Systems for Enhanced Transparent Heat Insulation
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Structural Engineering in Sn-Doped WOsub.3 Multi-Phase Systems for Enhanced Transparent Heat Insulation
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Journal Article
Structural Engineering in Sn-Doped WOsub.3 Multi-Phase Systems for Enhanced Transparent Heat Insulation
2025
Overview
Building energy conservation through the development of transparent thermal insulation materials that selectively block near-infrared radiation while maintaining visible light transmittance has emerged as a key strategy for global carbon neutrality. WO[sub.3] is a semiconductor oxide with near-infrared absorption capabilities. However, the limited absorption efficiency and narrow spectral coverage of pure WO[sub.3] significantly diminish its overall transparent thermal insulation performance, thereby restricting its practical application in energy-saving glass. Therefore, this study successfully prepared Sn-doped WO[sub.3] materials using a one-step hydrothermal method, controlling the Sn:W molar ratio from 0.1:1 to 2.0:1. Through evaluation of transparent thermal insulation performance of a series of Sn-doped WO[sub.3] samples, we found that Sn:W = 0.9:1 exhibited the most excellent performance, with NIR shielding efficiency reaching 93.9%, which was 1.84 times higher than pure WO[sub.3]. Moreover, this sample demonstrated a transparent thermal insulation index (THI) of 4.38, representing increases of 184% and 317%, respectively, compared to pure WO[sub.3]. These enhancements highlight the strong NIR absorption capability achieved by Sn-doped WO[sub.3] through structural regulation. When Sn doping reaches a certain concentration, it triggers a structural transformation of WO[sub.3] from monoclinic to tetragonal phase. After reaching the critical solubility threshold, phase separation occurs, forming a multiphase structure composed of a Sn-doped WO[sub.3] matrix and secondary SnO[sub.2] and WSn[sub.0.33]O[sub.3] phases, which synergistically enhance oxygen vacancy formation and W[sup.6+] to W[sup.5+] reduction, achieving excellent NIR absorption through small polaron hopping and localized surface plasmon resonance effects. This study provides important insights for developing high-performance transparent thermal insulation materials for energy-efficient buildings.
Publisher
MDPI AG
