Shuqi Wang

TL;DR: In this article, a self-adjusting polytetrafluoroethylene (PTFE)/TiO2 organic-inorganic double-layer coatings are designed on titanium alloy using thermal field and gradient pressure field enhanced plasma electrolytic oxidation (TGEPEO), which leads to the in-situ incorporation of PTFE nano-particles into the bottom TiO2 ceramic coating.

TL;DR: This all-inorganic phosphoric acid-based geopolymer (PGEO) paint showed robust radiative cooling performance and good comprehensive performance in terms of heat endurance, mechanical strength, and resistance to intense proton radiation, showing its promising applications in spacecraft, buildings, and communication base stations.

TL;DR: A novel Plasma-enhanced High temperature Liquid-phase assisted Oxidation and Crosslinking (PHLOC) in-situ co-growth strategy to design superhydrophobic nanocomposite coating on metals based on organic-inorganic multilayer structure that demonstrates excellent high-temperature endurance, thermal cycling stability of 500 ℃ and thermal repairability ofsuperhydrophobicity.

TL;DR: In this article, a biologically inspired passive radiative cooling dual-layer coating (Bio-PRC) is synthesized by a facile but efficient strategy, after the discovery of longhorned beetles' thermoregulatory behavior with multiscale fluffs, where an adjustable polymer-like layer with a hierarchical micropattern is constructed in various ceramic bottom skeletons, integrating multifunctional components with interlaced "ridge-like" architectures.

TL;DR: In this paper, the authors optimized both the sunlight transmission and infrared thermal irradiation by modeling the size-dependent scattering and absorption of light by SiO2 spheres embedded in a polymer matrix, and found that the use of nanospheres (20nm) enabled both high sunlight transmittance (> 90%) and infrared emissivity (~0.85).