Electrospun porous nanofibers have gained a lot of interest recently in various fields because of their adjustable porous structure, high specific surface area, and large number of active sites, which can further enhance the performance of materials. This paper provides an overview of the common polymers, preparation, and applications of electrospun porous nanofibers. Firstly, the polymers commonly used to construct porous structures and the main pore-forming methods in porous nanofibers by electrospinning, namely the template method and phase separation method, are introduced. Secondly, recent applications of electrospun porous nanofibers in air purification, water treatment, energy storage, biomedicine, food packaging, sensor, sound and wave absorption, flame retardant, and heat insulation are reviewed. Finally, the challenges and possible research directions for the future study of electrospun porous nanofibers are discussed.

/pdf/recent-progress-of-the-preparation-and-application-of-3jcv6q4y.pdf

Recent Progress of the Preparation and Application of Electrospun Porous Nanofibers

Preparation of CTS/PAMAM/SA/Ca2+ hydrogel and its adsorption performance for heavy metal ions

Electrospun carbon nanofibres: preparation, characterization and application for adsorption of pollutants from water and air

Mechanical properties and microstructure evolution of two ecological slope-protection materials under dry-wet cycles

The use of electrospun nanofibrous membranes for the treatment of dyehouse effluent is drawing attention because of their high surface area, and dye adsorption capability. In this work, nanofibrous membranes of S-sulfonated wool keratin protein/poly(vinyl alcohol) or PVA were prepared by electrospinning, and their effectiveness as an adsorbent for the removal of cationic methylene blue (MB) dye was studied. The electrospun nanofibers fabricated from keratin/PVA had a considerably finer average diameter (79.0 nm) compared to the average diameter (255.4 nm) exhibited by nanofibers produced from PVA alone. The optimal adsorption capacity was attained at a pH value close to neutral at ambient temperature (238.7 mg g−1), and the pseudo-second-order model was determined to be a reliable fit for the experimental data. Based on the fitted Langmuir model and MB adsorption data, the adsorption mechanism followed a monolayer pattern on the surface of the membrane. The MB dye adsorption capacity was slightly influenced by the presence of sodium chloride. The study demonstrated that the PVA/keratin nanofibrous membrane exhibited good reusability as only a small loss in absorption capacity was observed after three recycling and reuses. The developed biosorbent could be suitable for the high removal of dyes from textile dyehouse effluent. 

Separation of cationic methylene blue dye from its aqueous solution by S-sulfonated wool keratin-based sustainable electrospun nanofibrous membrane biosorbent

To improve the adsorption performance of carbon materials, novel ZnO nanoparticle-incorporated porous carbon nanofibers (Zn@PCNFs) were prepared via an electrospinning technique. A facile one-step fabrication strategy was proposed to simultaneously complete the carbonization of a peroxided polyacrylonitrile framework, the activating treatment caused by ZnO reducing to Zn, and the pore generation caused by evaporation of reduced Zn with a low melting point. The influences of the pH, ion category, and concentration on methylene blue adsorption were investigated. The physical–chemical characterizations showed that ZnO was homogeneously distributed on the nanofibers and micropores were generated. The adsorption results revealed that an efficient adsorption was obtained within a large range of pH values through different adsorption models, which was accelerated by increasing the temperature. Therefore, the novel Zn@PCNFs are anticipated to be applied in the future as an effective dye waste adsorbent.

https://pubs.acs.org/doi/pdf/10.1021/acsomega.1c05729

Preparation of ZnO-Incorporated Porous Carbon Nanofibers and Adsorption Performance Investigation on Methylene Blue

The strategy of solar-driven evaporation has been proved promising in seawater desalination and wastewater purification to address urgent crisis of drinking water without consuming fossil energy. However, preserving the heat...

Spontaneous thermal preserving and anti-gravitational water pumping Al2O3 fibers enhanced flexible nonwoven for high-performance and self-floating solar evaporator

UV stabilizer intercalated layered double hydroxide to enhance the thermal and UV degradation resistance of polypropylene fiber

The proliferation and differentiation of bone mesenchymal stem cells (BMSCs) in vitro are the key properties of bone tissue engineering for biomaterials. In this study, hydroxyapatite (HA) coated porous carbon nanofibres (PCNFs) were prepared to load dexamethasone (DEX) and further improve the differentiation ability of the BMSCs. Various characterisations were applied to reveal the DEX loading efficacy and biocompatibility, especially the differentiation strength. The results showed that HA could be successfully coated on the PCNFs by pretreating the surface using PEG conjugation. With an increase of HA, the particle diameter increased and the DEX loading decreased. In vitro experiments proved higher cell viability, alkaline phosphatase (ALP) activity, calcium nodule secretion ability and the RUNX2 protein expression, indicating that the as-prepared was of great biocompatibility and optimised osteoconductivity, which was attributed to the componential imitation to natural bone and the accelerated BMSCs differentiation. Consequently, the novel DEX loaded and HA coated PCNFs can provide potential applications in bone tissue regeneration.

Preparation of hydroxyapatite coated porous carbon nanofibres for DEX loading and enhancing differentiation of BMSCs

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Preparation of ZnO-Incorporated Porous Carbon Nanofibers and Adsorption Performance Investigation on Methylene Blue

Spontaneous thermal preserving and anti-gravitational water pumping Al2O3 fibers enhanced flexible nonwoven for high-performance and self-floating solar evaporator

UV stabilizer intercalated layered double hydroxide to enhance the thermal and UV degradation resistance of polypropylene fiber

Preparation of hydroxyapatite coated porous carbon nanofibres for DEX loading and enhancing differentiation of BMSCs