高温太阳光谱选择性吸收涂层的研究进展

doi:10.11896/cldb.24060008

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Abstract Photothermal conversion is currently the most popular and common way of solar energy utilizing worldwide, and solar selectively absorptive coating with high solar absorption and low infrared emissivity can significantly improve the efficiency. Compared with absorptive coatings used in medium and low temperatures (0＜T＜400 ℃), high temperature (T≥400 ℃) solar selectively absorptive coatings show great potential for development and applicative prospects. However, the aging and failure of them at high-temperatures limit their applications. Therefore, there is an urgent need to develop solar selectively absorptive coatings with excellent spectral selectivity and high-temperature thermal stability. In this paper, the design mechanism of solar selectively absorptive coating is outlined. And the types and latest developments of absorptive coatings with high-temperature thermal stability are summarized, mainly including bimetallic ceramics, transition metal compounds, and high-entropy alloy nitride multilayer structures. The main failure mechanisms and thermal stability enhancement strategies are classified and discussed. At the same time, the preparation processes of various high-temperature absorptive coatings are discussed, and accelerated aging tests and life predictive methods are summarized. Finally the problems and research directions faced by high-temperature solar selectively absorptive coatings are pointed out and discussed.

Key words： high-temperature solar selectively absorptive coating photothermal conversion thermal stability accelerated aging test life prediction

Published: 25 July 2025 Online: 2025-07-29

CLC number:	TK51
	TB34

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	DOU Yu
	FAN Tongxiang

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DOU Yu,FAN Tongxiang. Research Progress of High-temperature Solar Selectively Absorptive Coatings[J]. Materials Reports, 2025, 39(14): 24060008-11.

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https://www.mater-rep.com/EN/10.11896/cldb.24060008 OR https://www.mater-rep.com/EN/Y2025/V39/I14/24060008

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