Preparation and thermal reflectivity of nickel antimony titanium yellow rutile coated hollow glass microspheres composite pigment

Zeng, Guoxun; Yang, Jing; Hong, Renpeng; Li, Zhenghui; Yuan-wu, Chen; Liang, Feng; Wu, Qigang; Liu, Liying; Jiang, Xiangyang

doi:10.1016/j.ceramint.2018.02.025

Cited by 14 publications

(5 citation statements)

References 20 publications

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“…In 2018, Zeng and coworkers experimented with a yellow composite pigment comprising a core‐shell structure of HGM coated with nickel antimony yellow titanium rutile (TiNiY). [ 51 ] As a complex inorganic color pigment, TiNiY has a good heat reflectance (high NIR reflectance) on its own. However, due to its relatively high mass density, it cannot be well‐dispersed in resins since the pigment particles tend to settle to the bottom.…”

Section: Reflective Core‐shell Micro‐/nano‐structuresmentioning

confidence: 99%

Core‐Shell Micro‐ and Nano‐Structures for The Modification of Light‐Surface Interactions

Yeo,

Yu Tan

et al. 2023

Advanced Optical Materials

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Controlling how a material interacts with light is key to optimizing its optical properties to fit a desired function or application. The most straightforward approach is to chemically or physically modify the surface exposed to incident light. An effective method of surface modification is based on the addition of core‐shell structures at the surface. Of particular importance to many technological applications are core‐shell structures with dimensions comparable to the wavelengths of light extending from the UV up to the near‐IR region of the electromagnetic spectrum, which coincides with the major part of the solar spectrum. Surface modification approaches to tailor the optical properties of materials in this range of wavelengths are increasingly relevant in the context of materials and devices used in sustainable energy applications, such as solar cells and heat‐reflective paints. These materials are useful to mitigate the current energy and climate crises by allowing for enhanced energy harvesting and improved thermal management, respectively. Here, recent progress in the fabrication and application of core‐shell micro‐/nano‐structures for the modification of light interaction with surfaces is highlighted. Some limitations and future directions for the design of core‐shell materials are also discussed.

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Section: Reflective Core‐shell Micro‐/nano‐structuresmentioning

confidence: 99%

Core‐Shell Micro‐ and Nano‐Structures for The Modification of Light‐Surface Interactions

Yeo,

Yu Tan

et al. 2023

Advanced Optical Materials

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“…The cement-based composites made from graphene nano-platelets (GN) and HGMs were prepared and its electromagnetic waves absorbing properties were researched by Lv et al [156]. HGM@TiNiY pigment with core-shell structure which has good thermal reflectivity has been prepared by a novel mixing slurry-sintering method, according to the knowledge of the Zeng et al [157]. In the studies of Huang et al [158] the fibre taper I x microsphere coupled device with WGM is used to efficiently generate the UC luminescence, about 5 times than the case of optical fibre end directly illuminating.…”

Section: Figure 22mentioning

confidence: 99%

Glass Microspheres

Karasu

DEMİREL

ÖZTUVAN

et al. 2019

El-Cezeri Fen Ve Mühendislik Dergisi

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Glass microspheres are microscopic spheres of glass manufactured for a wide variety of uses in thermal insulation coating, putty, plastic casting polyester, radome, synthetic foam, adhesives, printed circuit board substrate, bowling, fan blades, and caulking materials, emulsion explosives, golf, sealant, pipeline insulation materials, artificial marble, PVC, low density oil drilling, light cement etc. Glass microspheres are usually between 1 and 1000 micrometres in diameter, although the sizes can range from 100 nanometres to 5 millimetres in diameter. Microspheres are spherical particles that can be distinguished into two categories; solid or hollow. This paper presented a general overview of glass microspheres.

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“…Zeng et al said that ATO-coated hollow glass microspheres could be used for thermal insulation applications. [13] Titanium dioxide and insulating glass microspheres were mixed and coated on cotton fabrics for thermal insulation, flame retardancy, and UV protection. [14] Jiao et al prepared thermally expanded microspheres with surface coating using polydisperse graphene oxide flakes.…”

Section: Introductionmentioning

confidence: 99%

Modification of Hollow Expanded Microspheres with Superior Thermal Insulation Properties and Their Applications

Zhao

Heng

Xu³

et al. 2023

Chemistry An Asian Journal

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Thermally expandable microspheres (TEMs) are hollow polymeric particles in which a blowing gas has been encapsulated. This property makes them excellent for thermal insulation applications, such as lightweight fillers. This study has developed a viable technology for further improving thermal insulation properties in the field that needs excellent thermal insulation of textile fabrics. The ATO/TEMs composites were designed and prepared to reduce sunlight radiation by the charge gravity method. The test results showed that the ATO‐coated TEMs effectively block thermal radiation from sunlight. The temperature difference between ATO/TEMs treated cotton and the uncoated cotton fabric was 9 °C, and the thermal conductivity coatings were 0.0432 W/m⋅K. The UPF value of ATO/TEMs (ILs) coated cotton fabric is 440, significantly higher than pure cotton. This approach can provide insight into the design of high‐performance solar insulation composite structures.

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Preparation and thermal reflectivity of nickel antimony titanium yellow rutile coated hollow glass microspheres composite pigment

Cited by 14 publications

References 20 publications

Core‐Shell Micro‐ and Nano‐Structures for The Modification of Light‐Surface Interactions

Core‐Shell Micro‐ and Nano‐Structures for The Modification of Light‐Surface Interactions

Glass Microspheres

Modification of Hollow Expanded Microspheres with Superior Thermal Insulation Properties and Their Applications

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