2025-08-22 中国科学院(CAS)
<関連情報>
- https://english.cas.cn/newsroom/research_news/chem/202508/t20250822_1051239.shtml
- https://www.sciencedirect.com/science/article/abs/pii/S0304389425021375?via%3Dihub
高性能空気濾過用高柔軟性・多機能性リヨセル-玄武岩繊維濾材 Highly flexible and multifunctional lyocell-basalt fiber filter media for high-performance air filtration
Ze-Xin Chen, Desalegn Atalie, Hui Li, Ming-Cheng Gao, Peng-Cheng Ma
Journal of Hazardous Materials Available online: 11 July 2025
DOI:https://doi.org/10.1016/j.jhazmat.2025.139221
Graphical Abstract
Highlights
- Highly flexible and robust filter prepared from lyocell and basalt fiber (LC/BF).
- High filtration (97.7 %) achieved for PM0.3 and with effective SO2 adsorption.
- BF improved heat resistance, bursting (by 136.5 %), and tear strength (by 128.9 %).
- The filter had better breathability, thermal stability, and antibacterial properties.
- LC/BF-ZIF-8 filters are the best candidate for fine PM and pollutant removal.
Abstract
Cellulose-based functionalized fabrics are emerging as promising air purification filter materials. However, limitations such as poor moisture resistance, low strength, and heat sensitivity are challenging in the practical application of fine particulate matter filtration. Here, we developed a flexible and multifunctional lyocell/basalt fiber (LC/BF) filter fabric using a wet-laid process, avoiding the need for additional binders. The filter fabric was further enhanced with ZIF-8 functionalization to achieve considerable PM0.3 and sulfur dioxide removal. The incorporation of LC fibrillated nanofibers significantly improved the fabric’s flexibility, light weight, and filtration performance. The addition of BF reduced pressure drops and significantly increased burst (136.5 %) and tear strength (128.9 %) compared to the pure LC filter media. The BF also helps improve moisture (55.8 %), thermal, and chemical resistance. The resulting LC/BF-25@ZIF-8 fabric demonstrated a remarkable filtration efficiency of 97.72 % for PM0.3 particles. This functionalization also led to significant enhancements in gas adsorption, specifically 93 % improvement for SO2 and 111.5 % for the volatile organic compound methylbenzene adsorption, showcasing synergetic simultaneous capture capabilities. Furthermore, excellent antibacterial activity against E. coli, S. aureus, and S. pneumoniae was obtained, with inhibition rates exceeding 99.8–99.9 %. This eco-friendly approach, combining the distinctive properties of LC/BF and ZIF-8, offers a promising solution for multifunctional advanced air filtration applications, such as fitting into sophisticated equipment, combined gas adsorption, and environmental tolerance.
