In research published (DOI: 10.1007/s10118-024-3109-5) on April 10, 2024, in the Chinese Journal of Polymer Science, scientists from the Beijing Institute of Graphic Communication and Beihang University unveiled a double-stranded yarn with alternating hydrophobic and hydrophilic properties. Inspired by the water-collecting abilities of desert beetles and spider silk, the yarn, produced using electrospinning and twisting techniques, is designed for high-efficiency fog collection, addressing the critical need for sustainable water sources.
The research highlights the development of a double-stranded yarn made from hydrophobic poly vinylidene fluoride-co-hexafluoropropylene (PVDF-HFP) and hydrophilic polyacrylonitrile (PAN) nanofibers, inspired by natural fog-collecting organisms like desert beetles and spider silk. Using electrospinning and twisting techniques, the team engineered the yarn with alternating hydrophobic and hydrophilic segments, creating a structure that mimics nature’s water-harvesting mechanisms. The hydrophobic sections promote rapid water droplet accumulation, while the hydrophilic sections enhance the transportation of these droplets, allowing for faster coalescence and collection. When tested in a controlled fog environment, this yarn demonstrated a significant improvement in water collection efficiency, achieving a rate of 3.20 g·h−1·cm−2. The combination of hydrophobic water capture and hydrophilic water transport proved to be far more effective than using homogeneous yarns. This innovation presents a scalable solution, offering high performance in fog-rich environments, and could be vital for improving water access in drought-prone regions.
Prof. Yong Zhao from Beihang University, an expert in bioinspired materials, stated, “This advancement shows how biomimicry can drive highly efficient and sustainable solutions to global challenges such as water scarcity. The alternating wettability design emulates nature’s precision, significantly boosting fog collection performance.”
The research has broad implications, particularly for regions facing severe water shortages. The yarn’s scalable and efficient design makes it ideal for use in fog-prone areas, offering a reliable source of freshwater. This breakthrough also paves the way for future innovations in water-harvesting technologies, with the potential to enhance the sustainability of atmospheric water collection systems worldwide.