Your search keyword '"Liu, Yongwei"' showing total 2 results

1. Influence of glass matrix SiO2–B2O3–NaF on the formation of NIR-shielding functional units in energy-saving window glasses.

Author

Yang, Guang, Liu, Yongwei, Yang, Chuanfan, Xia, Fang, Wu, Yupeng, Shpotyuk, Yaroslav, Takats, Viktor, Zeng, Huidan, Xu, Yinsheng, Chen, Hongfei, and Gao, Yanfeng

Subjects

*CRYSTAL glass, *GLASS, *THERMAL insulation, *GLASS construction, *TUNGSTEN bronze, *GLASS coatings, *TUNGSTEN, *RAW materials, *METALLIC glasses

Abstract

This work presents the influence of glass matrix SiO 2 –B 2 O 3 –NaF on the formation of near-infrared (NIR)-shielding functional units in energy-saving glass windows. The structural analyses by XRD, XPS, and Raman confirmed that the NIR-shielding performance is insensitive to SiO 2 or B 2 O 3 glass network formers but is significantly impacted by the concentration of NaF. This is because the presence of a reasonable amount of NaF provides the much-needed sodium for the formation of NIR-shielding functional units Na 5 W 14 O 44 but too much NaF (>22 mol.%) can inhibit the formation of Na 5 W 14 O 44 by transforming the W– O –W chain in the interconnected [WO 6 ] and [WO 4 ] polyhedrons into W–O- bonds. By adjusting NaF to the optimal level (16 mol.%) and adding only a small amount of H 2 WO 4 (1.9 mol.%) as the tungsten source in the raw materials, excellent optical properties and thermal insulation performance have been achieved in the produced bulk glass, with a high transmission of 65.8% at 550 nm in the visible light region and a low transmission of 6.6% at 1550 nm in the NIR region. This performance is much better than soda lime glass and ITO glass and is comparable to cesium tungsten bronze-based membrane coated glass. This study paves a way for glass composition design to achieve high NIR-shielding performance with the minimum amount of tungsten source, leading to cost-effective glass fabrication and enhanced mechanical strength of energy-saving glass windows. [ABSTRACT FROM AUTHOR]

Published

2023

2. Effects of alkali metal ion on imprinting GRIN microstructure in GeS2-Ga2S3-MCl (M=Na, K, Cs) glasses for visible to mid-infrared microgratings.

Author

Liu, Bin, Mo, Yaoyao, Liu, Yongwei, Lu, Yunjun, He, Xiaoyan, Xu, Yinsheng, Lipovskii, Andrey, and Yang, Guang

Subjects

*ALKALI metal ions, *ALKALI metals, *IMPRINTED polymers, *MICROSTRUCTURE, *REFRACTIVE index, *DEGREES of freedom, *GLASS

Abstract

Gradient refractive index (GRIN) micro-optics present unique opportunities for control of the chromatic properties, new degrees of freedom for optical design as well as the potential for use in new optical system applications. GRIN microgratings were imprinted in GeS 2 -Ga 2 S 3 -MCl (M = Na, K, Cs) chalcohalide glasses by microthermal poling, and the effects of the type and concentration of alkali cations on their performance were investigated. Two effective imprinting formation regions of the GRIN microstructure based on the poling saturation voltage (U s) and glass composition are observed at fixed poling time and temperature. The U s increases from 140 to 750 and 2600 V in accordance with the activation energy (E a) of alkali ions (Na+ to K+ and Cs+) increasing from 45.15 to 58.62 and 92.58 kJ/mol for studied samples. The saturated numbers of diffraction order (N s) of the gratings in these samples are 7, 9 and 6, respectively, the highest number being provided by the K+-containing sample. This is in accordance with imprinting-induced phase differences (0.14λ, 0.19λ and 0.09λ) measured in the fabricated samples containing Na+, K+ and Cs+ ions. Furthermore, the U s of samples decreases from 1500 to 300 V with four concentrations of K+ from 10 to 30%, associated with their E a of K+ decreasing from 69.62 to 53.46 kJ/mol, while N s increases from 8 to 14, which is attributed to the increase of the phase difference in the GRIN structures. The controllable GRIN microstructures are realized by adjusting the type and concentration of alkali cations in chalcohalide glasses, which is expected to drive the design of broadband GRIN microgratings. [ABSTRACT FROM AUTHOR]

Published

2022