Synergistic enhancement of external electrical energy in PM filtration with Cu-HHTP@CuO nanowire arrays coated copper mesh

Developing multifunctional purification systems that combine air filtration and antibacterial functionality is a challenging task. However, in designing air filtration materials, achieving a balance between filtration efficiency and pressure drop remains a significant challenge. In this study, we developed a novel filtration material composed of hierarchically 3D Cu-HHTP nanowiskers coated CuO nanowires that were grown in-situ on a copper mesh. Benefitted from the intrinsically electrical conductivity of Cu-HHTP, we combined the composite material with external electrical energy for air filtration. By applying lower electric potential directly (voltage of 5 V), the 3D conductive mesh filter exhibited excellent performances in terms of the PM2.5 removal efficiency (∼99.7%), pressure drop (∼32 Pa at 2 cm s -1), and quality factor (0.187 at 2 cm s -1). Furthermore, after ten cycles of filtration and cleaning, the material maintained a high PM removal rate. In addition to its excellent filtration performance, the composite metal mesh also exhibited outstanding antibacterial activity against both E. coli and S. aureus. The electro-mechanical stability and recyclability of the composite filter make it a cost-effective and environmentally friendly solution for air purification, with promising potential for improving air quality.