Wood-based composite phase change materials with self-cleaning superhydrophobic surface for thermal energy storage
DOI: 10.1016/j.apenergy.2019.114481 Corpus ID: 214161811 Wood-based composite phase change materials with self-cleaning superhydrophobic surface for thermal energy storage @article{Yang2020WoodbasedCP, title={Wood-based composite phase change
Multifunctional Photothermal Phase-Change
A photothermal superhydrophobic surface is considered to be useful for preventing ice formation because of its environmentally friendly, energy-saving, and excellent anti-icing/de-icing
Enhanced thermal conductivity of a superhydrophobic thermal energy storage
Enhanced thermal conductivity of a superhydrophobic thermal energy storage coating based on artificially cultured diatom frustules October 2023 Applied Energy 347:121462 DOI: 10.1016/j.apenergy
Superhydrophobic, multi-responsive and flexible bottlebrush
Multi-responsive form-stable phase change materials (FSPCMs) can convert various forms of energy to latent heat for storage and have attracted extensive attention.
What is a Superhydrophobic Material?
There is a potential to leverage novel superhydrophobic surfaces into applications in energy storage devices, coatings for protecting electronic devices in humid environments, preventing water corrosion, anti-icing, and desalination.
The robust fluoride-free superhydrophobic thermal energy
Multifunctional phase change materials-based thermal energy storage technology is an important way to save energy by capturing huge amounts of thermal energy during solar
Photothermal materials with energy-storage properties provide an energy
Photothermal superhydrophobic surfaces are one of the most promising anti‐/deicing materials, yet they are limited by the low energy density and intermittent nature of solar energy.
Superhydrophobic multi-shell hollow microsphere confined phase
4 · DSC was employed to evaluate the thermal energy storage capabilities of pure ODA, MSHS@ODA, and MSHS@ODA after 50 and 100 thermal cycles, assessing the
The robust fluoride-free superhydrophobic thermal energy
Herein, superhydrophobic thermal energy storage coating is realized by spraying mesoporous superhydrophobic C@SiO 2-HDTMS nanotubes (NTs), industrial paraffin wax (IPW), and ethyl α-cyanoacrylate (ECA) onto the substrate material for
Fast Self-Healing Superhydrophobic Thermal Energy Storage
A fully biomass-based ss-PCM, superhydrophobic thermal energy storage (STES) coating by employing beeswax (BW) as phase change materials (PCMs) and DFs as supporting materials via a facile spraying method is prepared. Diatom frustules (DFs) with delicate hierarchical pores and a large specific surface area are extracted from artificially cultured
Large-Scale Fabrication of a Robust Superhydrophobic Thermal Energy Storage Sprayable
Yang et al. prepared a superhydrophobic TD/DW composite, and found that the calculated energy storage efficiency of the superhydrophobic TD/DW composite can reach 449.84% (Figure 16(b1-b3)) [147].
Innovative design of superhydrophobic thermal energy-storage materials by microencapsulation
We reported an innovative combination of superhydrophobic surface and thermal energy-storage material. • This idea was realized by microencapsulating PCM with a flower-like ZnO/SiO 2 shell. This material exhibits a
A novel flexible and fluoride-free superhydrophobic thermal energy storage coating for photothermal energy
The development of advanced multifunctional phase change materials (PCMs) for solar energy harvesting and storage is an important alternative to conventional energy sources. Herein, a novel flexible superhydrophobic thermal energy storage (FSTES) coating without fluoride is prepared by spraying mesoporous C@SiO 2
Large-Scale Fabrication of a Robust Superhydrophobic Thermal Energy Storage
We propose a facile and effective route for large-scale fabrication of a superhydrophobic thermal energy storage (STES) sprayable coating with heat storage capacity and superhydrophobicity based on polydivinylbenzene (PDVB) nanotubes (NTs). Herein, the STES coating was applied on wood by convenient spraying, and the PDVB
Superhydrophobic, multi-responsive and flexible bottlebrush-network-based form-stable phase change materials for thermal energy storage
The energy harvesting performance of current storage systems, however, is limited by the low thermal conductivity of PCMs, and the thermal conductivity enhancement of high-temperature molten salt
Nanomaterials | Free Full-Text | The Roles of Riblet
Riblet and superhydrophobic surfaces are two typical passive control technologies used to save energy. In this study, three microstructured samples—a micro-riblet surface (RS), a
Superhydrophobic multi-shell hollow microsphere confined phase change materials for solar photothermal conversion and energy storage
Semantic Scholar extracted view of "Superhydrophobic multi-shell hollow microsphere confined phase change materials for solar photothermal conversion and energy storage" by Jiyan Li et al. DOI: 10.1016/j.apenergy.2024.123193 Corpus ID: 269234068
A novel flexible and fluoride-free superhydrophobic thermal energy storage coating
Herein, a novel flexible superhydrophobic thermal energy storage (FSTES) coating without fluoride is prepared by spraying mesoporous [email protected]2 nanotubes (NTs) supporting materials, PCMs
A novel flexible and fluoride-free superhydrophobic thermal
Herein, a novel flexible superhydrophobic thermal energy storage (FSTES) coating without fluoride is prepared by spraying mesoporous C@SiO2
Superhydrophobic, multi-responsive and flexible bottlebrush-network-based form-stable phase change materials for thermal energy storage
Multi-responsive form-stable phase change materials (FSPCMs) can convert various forms of energy to latent heat for storage and have attracted extensive attention. Superhydrophobic surfaces are garnering constant interest and can improve the long-term solar energy utilization and environmental adaptability o
The robust fluoride-free superhydrophobic thermal energy storage coating for efficient energy storage
Herein, superhydrophobic thermal energy storage coating is realized by spraying mesoporous superhydrophobic C@SiO2-HDTMS nanotubes (NTs), industrial paraffin wax (IPW), and ethyl α-cyanoacrylate
Recent development and emerging applications of robust biomimetic superhydrophobic
The development of superhydrophobic wood facilitates its emerging applications in anti-icing, oil–water separation, self-healing, and energy storage and conversion. As such, this review provides fundamental guidelines for designing superhydrophobic wood.
Advanced Anti-Icing Strategies and Technologies by Macrostructured Photothermal Storage Superhydrophobic
Currently, superhydrophobic surfaces (inspired by the lotus effect) aided anti-icing attracts intensive attention due to their energy-free property. Here, recent advances in anti-icing by design and functionalization of superhydrophobic surfaces
Superhydrophobic Coatings from Beeswax‐in‐Water Emulsions with Latent Heat Storage
Beeswax‐rich coatings such as the ones with 1:1 beeswax:polymer ratio or more, including the superhydrophobic ones, demonstrate promising latent heat storage characteristics, suitable for thermal management applications. Electron microscopy studies show that as a result of emulsification, the polymer encapsulates the wax droplets/particles as
Superhydrophobic multi-shell hollow microsphere confined phase change materials for solar photothermal conversion and energy storage
The phase change enthalpy can reach 130.7 J·g−1 and maintain a high energy storage density during 100 cyclic phase change tests. Specifically, MSHS@ODA decreases the operating temperature of lithium-ion batteries by 8 °C during discharge, ensuring their stable operation within the optimal temperature range.
Wood-based composite phase change materials with self-cleaning superhydrophobic surface for thermal energy storage
When the spray-coating method is used for the preparation of SHWSs, it is supposed to simultaneously form hierarchical roughness and low-energy surfaces. After a curing and/or drying process (i.e
Superhydrophobic, multi-responsive and flexible bottlebrush-network-based form-stable phase change materials for thermal energy storage
Multi-responsive form-stable phase change materials (FSPCMs) can convert various forms of energy to latent heat for storage and have attracted extensive attention. Superhydrophobic surfaces are garnering constant interest and can improve the long-term solar energy utilization and environmental adaptability of multi-responsive
Large-Scale Fabrication of a Robust Superhydrophobic Thermal
We propose a facile and effective route for large-scale fabrication of a superhydrophobic thermal energy storage (STES) sprayable coating with heat storage
Recent advances in self-healing superhydrophobic coatings
Pore substrates, such as fabrics, sponges, loofah capsules, etc., facilitate the storage and migration of low surface energy materials. Self-healing superhydrophobic cotton fabrics can be prepared by simply soaking in
(PDF) Superhydrophobic Coatings from
Hence, the coatings can be heated well above. the melting point of beeswax ( ≈62 C) and used for latent heat. storage during their cooling phase. This water-based coating. process along with eco
Concurrent Superhydrophobicity and Thermal Energy
Against thermal attack up to approximately 240 °C, the microstructure of MCs is nearly intact to avoid an obvious leakage of encapsulated PCM at high temperature, and meanwhile superhydrophobicity of MCs is
Innovative design of superhydrophobic thermal energy-storage
In the present work, the superhydrophobic thermal energy-storage material was designed by constructing a superhydrophobic surface on the as-synthesized microcapsules. The n -docosane used as a paraffin-type PCM was first microencapsulated with SiO 2, and then a ZnO layer was fabricated onto the as-synthesized microcapsules.
Large-Scale Fabrication of a Robust Superhydrophobic Thermal Energy Storage Sprayable
We propose a facile and effective route for large-scale fabrication of a superhydrophobic thermal energy storage (STES) sprayable coating with heat storage capacity and superhydrophobicity based on polydivinylbenzene (PDVB) nanotubes (NTs). Herein, the STES coating was applied on wood by convenient
Superhydrophobic Coatings from Beeswax‐in‐Water Emulsions with Latent Heat Storage
Beeswax particles are homogenously emulsified in commercial aqueous polymer dispersion, without additional dispersing agents and surfactants. Emulsions display very good stability with wax droplet size distribution around 350 nm. The wax to polymer ratio in the emulsions can be tuned without compromising emulsion stability. The
Fast Self-Healing Superhydrophobic Thermal Energy Storage
Request PDF | On Sep 28, 2021, Haoyang Sun and others published Fast Self-Healing Superhydrophobic Thermal Energy Storage Coatings Fabricated by Bio-Based Beeswax and Artificially Cultivated
