Highly efficient and durable solar thermal energy harvesting <i>via</i> scalable hierarchical coatings inspired by stony corals

Torres, Juan F.; Tsuda, Kaoru; Murakami, Yasushi; Guo, Yifan; Hosseini, Sahar; Asselineau, Charles-Alexis; Taheri, Mahdiar; Drewes, Kurt; Tricoli, Antonio; Lipiński, Wojciech; Coventry, Joe

doi:10.1039/d1ee03028k

Cited by 43 publications

(34 citation statements)

References 57 publications

(115 reference statements)

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“…Liu et al [15] reported a TiAlON-based nanometer multilayer coatings, whose solar selectivity was 0.936/0.17 with a slight variation of 0.922/0.175 and which was stabilized for 50 h in 550 °C air. Juan F. Torres et al [18] reported Al and Ti-SiO2 coralloid coatings, which exhibited ultrahigh stability after being aged in high-temperature (≥ 800 °C) air for over 2000 h. Beibei Lu et al [9] fabricated a composite coatings of Si3N4, a-Si, Ag, and Cr2O3, which showed no obvious interfacial diffusion after being annealed at 400 °C in air. Hao Wang et al [19] designed a SiO2-Si3N4-W-SiO2-W coatings, which remained stable after being heated for 72 h at 400 °C in air.…”

Section: Introductionmentioning

confidence: 99%

Research on the Thermal Stability in High-Temperature Air of Cr-Fe Composite Oxide Solar Coatings by Chemical-Colored of Stainless Steel

Song

et al. 2023

Processes

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The stainless steel chemical coloration demonstrates excellent repeatability of process when adopted to fabricate solar selective absorber coatings (SSACs) on TTS445J1 stainless steel base material. The optical performance, morphology, and composition of coatings are characterized by UV-3600, IR-Affinity-1, SEM, EDS, etc. The experimental results suggest that the Cr-Fe composite oxides with coatings in a spinel structure obtained by chemical coloration on a stainless steel surface exhibit outstanding spectral selectivity, with α/ε = 0.9334/0.1326. The coatings were generated by the direct reaction between the stainless steel substrate composition and the coloring solution, which changes the traditional way of combining the coating with the substrate by physical methods. Comparing the SEM images of the coatings before and after aging at 500 °C in air, we noticed no significant changes at the interface between the coatings and the substrate, indicating excellent coating adhesion. At the same time, the substrate grains did not change much after the chemical reaction of the stainless steel substrate, indicating that the oxidation resistance of the stainless steel substrate was not weakened. Finally, the Cr-Fe composite oxide exhibited excellent thermal stability in air. Based upon a microstructure analysis, the Performance Creation (PC) is 0.01 after aging at 500 °C for 200 h in high-temperature air, primarily because of the loss of H2O molecules from the hydrates in the coatings. After aging for 800 h, PC = 0.0458. After the aging hours are extended to 1000 h, PC = 0.0762. During the aging process at high temperature, the coatings of the Cr-Fe composite oxides maintained stable composition and phase structures. The decay in optical performance is due mainly to the reconstruction of the surface morphology of the coatings as a result of the largening of grains.

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Section: Introductionmentioning

confidence: 99%

Research on the Thermal Stability in High-Temperature Air of Cr-Fe Composite Oxide Solar Coatings by Chemical-Colored of Stainless Steel

Song

et al. 2023

Processes

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“…24,25 In this approach, photothermal materials, as light harvesters and opticalthermal energy converters, are the key elements. 26 According to previous reports, inorganic materials, such as precious metals 27 and semiconductors, 28,29 and organic materials, such as carbon-based materials 30,31 and conjugated polymers, 32 have been investigated for solar steam generation. However, the extensive application of these new technologies is limited due to the high material costs and complex fabrication procedures.…”

Section: Introductionmentioning

confidence: 99%

A highly efficient and stable solar energy-driven device using lignocellulosic biomass Juncus effusus for the recovery of ethanol–water mixture

Zhou

Xia

et al. 2022

Green Chem.

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“…Since the P t is unalterable and depends on the local weather, the question becomes how to convert P t to P v as much as possible while suppressing P c and P r . Therefore, high solar to vapor efficiency is significantly related to (1) optimization of the nanophotonic structure to improve photothermal conversion (reduce P r loss) − and (2) thermal management to reduce heat conducting to bulk water (reduce P c loss). − While much of existing work has focused on either of these two factors, it is necessary to develop integrated evaporators with high light absorption efficiency and low heat loss. In addition, water supply is also important, and efforts have been made in this vein by constructing water transport channels, − designing evaporators with a shell layer for evaporation and a core layer for insulation, , and designing hydrogel-substrate-based evaporators. , …”

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confidence: 99%

“…Because of the synergy of the CuO NSs and C-NPs, the micro/nanostructured C@CuO exhibited over 98.8% light absorption in the ultraviolet band (220–380 nm), over 99.0% in the visible (380–760 nm) band, and over 93.9% in the infrared band (760–2500 nm) across the whole solar spectrum, as Figure d indicates in the red curve. The high light absorption efficiency of C@CuO is favorable for the water evaporation because of the composition synergy and structurally induced multiple internal reflections …”

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confidence: 99%

High-Performance Janus Solar Evaporator for Water Purification with Broad Spectrum Absorption and Ultralow Heat Loss

Hou

Wang

et al. 2022

ACS Energy Lett.

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Interfacial solar vapor generation offers a promising zero-CO 2 -consuming energy conversion technology for the production of renewable clean water. The key for boosting solar vapor efficiency relies on the rational design of materials composition and structure at the micro/nanoscale to improve light utilization. Here, we demonstrate a Janus evaporator based on a hydrophilic carbon-black-decorated copper oxide (C@CuO) membrane as the light-absorbing layer and an opposite hydrophobic polymer nanofibers as the thermal insulation layer, which enables efficient energy utilization and vapor generation through a synergistic light absorption and thermal confinement strategy. In addition, the hydrated C@CuO surface reduces vaporization enthalpy that accelerates the efficient evaporation of water. A high evaporation rate of 1.88 kg m −2 h −1 is achieved by the Janus evaporator under 1 sun irradiation. This high photothermal conversion rate and ultralow heat loss synergistic engineering offers a bright future for high-efficiency solar water purification applications.

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Highly efficient and durable solar thermal energy harvesting via scalable hierarchical coatings inspired by stony corals

Abstract: Stony coral morphology inspires ultra-stable sunlight absorber structure with highest reported absorptance for high-temperature solar thermal applications.

Cited by 43 publications

References 57 publications

Research on the Thermal Stability in High-Temperature Air of Cr-Fe Composite Oxide Solar Coatings by Chemical-Colored of Stainless Steel

Research on the Thermal Stability in High-Temperature Air of Cr-Fe Composite Oxide Solar Coatings by Chemical-Colored of Stainless Steel

A highly efficient and stable solar energy-driven device using lignocellulosic biomass Juncus effusus for the recovery of ethanol–water mixture

High-Performance Janus Solar Evaporator for Water Purification with Broad Spectrum Absorption and Ultralow Heat Loss

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