Abstract:The emergence of
Steiner minimal tree is of fundamental importance,
and designing such geometric structure and developing its application
have practical effect in material engineering and biomedicine. We
used a cutting-edge nanotechnology, electrospinning/netting, to generate
a Steiner geometrical poly(vinylidene fluoride) (PVDF) nanofiber/nanonet
filter for removing airborne particulate matter (PM). Manipulation
of surface morphologies by precise control of charged situation enabled
the creation of two-dimen… Show more
“…Compared with a blank wire mesh with an original pressure drop of 14 Pa and flow rate of 3.5 m s −1 , fibrous filters with 86% transmittance showed a smaller change. Besides, we have compared the filters in this work with other reported fibrous filters (Li et al., 2018a, Li et al., 2018b, Liu et al., 2015, Wang et al., 2014, Zhang et al., 2016a, Zhang et al., 2016b, Zhang et al., 2016c, Zhao et al., 2017a, Zhao et al., 2017b, Zuo et al., 2017), which clearly shows that PDMS/PMMA-CS (chitosan) nanofiber filters have the best air filtration performance considering PM removal efficiency, pressure drop, and the QF (Figure S5). Figure 4Transparent Nanofiber Filters(A) Photographs of PDMS/PMMA-chitosan transparent air filters at different transparencies.(B and C) (B) PM 2.5 and PM 10 removal efficiency and (C) pressure drop and flow rate of transparent filters at different transmittances.…”
Summary
Particulate matter (PM) pollution has posed great threat to human health. This calls for versatile protection or treatment devices that are both efficient and easy to use. Herein, we have rationally designed a novel reusable bilayer fibrous filter consisting of electrospun superhydrophobic poly(methylmethacrylate)/polydimethylsiloxane fibers as the barrier for moisture ingression and superhydrophilic chitosan fibers for a PM capture efficiency of over 96% at optical transmittance of 86%. Furthermore, it could realize a high-level PM
2.5
capture efficiency (>98.23%) even after 100-h test during extremely hazardous air environment (PM
2.5
> 3,000 μg m
−3
) and retain a high PM removal efficiency (PM
2.5
> 98.39%) after five washing cycles. Besides, such membranes possessed high antibacterial activity at 96.5% for
E. coli
and 95.2% for
Staphylococcus aureus
. As a proof-of-concept study, continuous particle removing has been successfully demonstrated on a window screen to prevent particle pollution.
“…Compared with a blank wire mesh with an original pressure drop of 14 Pa and flow rate of 3.5 m s −1 , fibrous filters with 86% transmittance showed a smaller change. Besides, we have compared the filters in this work with other reported fibrous filters (Li et al., 2018a, Li et al., 2018b, Liu et al., 2015, Wang et al., 2014, Zhang et al., 2016a, Zhang et al., 2016b, Zhang et al., 2016c, Zhao et al., 2017a, Zhao et al., 2017b, Zuo et al., 2017), which clearly shows that PDMS/PMMA-CS (chitosan) nanofiber filters have the best air filtration performance considering PM removal efficiency, pressure drop, and the QF (Figure S5). Figure 4Transparent Nanofiber Filters(A) Photographs of PDMS/PMMA-chitosan transparent air filters at different transparencies.(B and C) (B) PM 2.5 and PM 10 removal efficiency and (C) pressure drop and flow rate of transparent filters at different transmittances.…”
Summary
Particulate matter (PM) pollution has posed great threat to human health. This calls for versatile protection or treatment devices that are both efficient and easy to use. Herein, we have rationally designed a novel reusable bilayer fibrous filter consisting of electrospun superhydrophobic poly(methylmethacrylate)/polydimethylsiloxane fibers as the barrier for moisture ingression and superhydrophilic chitosan fibers for a PM capture efficiency of over 96% at optical transmittance of 86%. Furthermore, it could realize a high-level PM
2.5
capture efficiency (>98.23%) even after 100-h test during extremely hazardous air environment (PM
2.5
> 3,000 μg m
−3
) and retain a high PM removal efficiency (PM
2.5
> 98.39%) after five washing cycles. Besides, such membranes possessed high antibacterial activity at 96.5% for
E. coli
and 95.2% for
Staphylococcus aureus
. As a proof-of-concept study, continuous particle removing has been successfully demonstrated on a window screen to prevent particle pollution.
“…The basic principle of the formation of 2D films could be due to the ejection of charged droplets from Taylor cone, which was triggered by the initiator of the surfactant TBAC. The ion–dipole interaction, between the cationic head group of TBAC and the polar nitrile group in PAN molecules, can effectively release chloride ions of TBAC, and thus further facilitate the polarization and charging of the precursor solution during electrospinning/netting (Figure e) . This is the principal feature in the aspect of solution regulation that distinguishes our strategy from other nanofiber/net fabrication methods.…”
Particulate matter (PM) pollution has posed a huge health and economic burden worldwide. Most existing air filters used to remove PMs are structurally monotonous, cumbersome, and inevitably suffer from the compromise between removal efficiency and air permeability; developing an advanced air filter that can overcome these limitations is of significance but highly challenging. Herein, a novel strategy to create ultrathin, high-performance air filters based on fluffy dual-network structured polyacrylonitrile nanofiber/ nets, via a humidity-induced electrospinning/netting technique, is reported. By tailoring the ejection and phase separation of the charged liquids, this approach causes 2D ultrafine (≈20 nm) nanonets tightly bonded with fluffy pseudo-3D nanofiber scaffolds to form dual-network structures, with controllable pore size and stacking density on a large scale. The resultant nanofiber/ net filters possess the integrated features of small pore size (<300 nm), high porosity (93.9%), low packing density, combined with desirable surface chemistry (4.3-D dipole moment), resulting in high-efficiency PM 0.3 removal (>99.99%), low air resistance (only <0.11% of atmosphere pressure), and promising long-term PM 2.5 purification. The synthesis of such materials may provide new insights into the design and development of high-performance filtration and separation materials for various applications.
“…The integrated filter with gradually varied pore structures and high porosity can efficiently capture airborne particles in a gradient manner with low air resistance. Very recently, Li et al also employed the electrospinning/netting process for the mass production of a reusable poly(vinylidene fluoride) nanofibre/nanonet air filter, which presented a high purification efficiency of 99.985% towards PM 0.26 and a low-pressure drop of 66.7 Pa [145].…”
Section: Engineering Of Multifunctional Masks and Mask Materialsmentioning
The increasing prevalence of infectious diseases in recent decades has posed a serious threat to public health. Routes of transmission differ, but the respiratory droplet or airborne route has the greatest potential to disrupt social intercourse, while being amenable to prevention by the humble face mask. Different types of masks give different levels of protection to the user. The ongoing COVID-19 pandemic has even resulted in a global shortage of face masks and the raw materials that go into them, driving individuals to self-produce masks from household items. At the same time, research has been accelerated towards improving the quality and performance of face masks, e.g., by introducing properties such as antimicrobial activity and superhydrophobicity. This review will cover mask-wearing from the public health perspective, the technical details of commercial and home-made masks, and recent advances in mask engineering, disinfection, and materials and discuss the sustainability of mask-wearing and mask production into the future.
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