High-performance air filtration materials are important
for addressing
the airborne pollutants. Herein, we propose an unprecedented access
to biodegradable poly(lactic acid) (PLA)-based MOFilters with excellent
filtering performance and antibacterial activity. The fabrication
involved a stepwise in situ growth of zeolitic imidazolate framework-8
(ZIF-8) crystals at the surface of microfibrous PLA membranes, followed
by mechanical polarization under high pressure and low temperature
(5 MPa, 40 °C) to trigger the ordered alignment of dipoles in
PLA chains and ZIF-8. The unique structural features allowed these
PLA-based MOFilters to achieve an exceptional combination of excellent
tensile properties, high dielectric constant (up to 2.4 F/m), and
enhanced surface potential as high as 4 kV. Arising from the remarkable
surface activity and electrostatic adsorption effect, a significant
increase (from over 12% to nearly 20%) in PM0.3 filtration
efficiency was observed for the PLA-based MOFilters compared to that
of pure PLA counterparts, with weak relation to the airflow velocities
(10–85 L/min). Moreover, the air resistance was controlled
at a considerably low level for all the MOFilters, that is, below
183 Pa even at 85 L/min. It is worth noting that distinct antibacterial
properties were achieved for the MOFilters, as illustrated by the
inhibitive rates of 87 and 100% against Escherichia
coli and Staphylococcus aureus, respectively. The proposed concept of PLA-based MOFilters offers
unprecedented multifunction integration, which may fuel the development
of biodegradable versatile filters with high capturing and antibacterial
performances yet desirable manufacturing feasibility.
Despite
the great potential in fabrication of biodegradable and
eco-friendly air filters by electrospinning poly(lactic acid) (PLA)
membranes, the filtering performance is frequently dwarfed by inadequate
physical sieving or electrostatic adsorption mechanisms to capture
airborne particulate matters (PMs). Here, using the parallel spinning
approach, the unique micro/nanoscale architecture was established
by conjugation of neighboring PLA nanofibers, creating bimodal fibers
in electrospun PLA membranes for the enhanced slip effect to significantly
reduce the air resistance. Moreover, the bone-like nanocrystalline
hydroxyapatite bioelectret (HABE) was exploited to enhance the dielectric
and polarization properties of electrospun PLA, accompanied by the
controlled generation of junctions induced by the microaggregation
of HABE (10–30 wt %). The incorporated HABE was supposed to
orderly align in the applied E-field and largely promote the charging
capability and surface potential, gradually increasing to 7.2 kV from
the lowest level of 2.5 kV for pure PLA. This was mainly attributed
to HABE-induced orientation of PLA backbone chains and CO
dipoles, as well as the interfacial charges trapped at the interphases
of HABE–PLA and crystalline region–amorphous PLA. Given
the multiple capturing mechanisms, the micro/nanostructured PLA/HABE
membranes were characterized by excellent and sustainable filtering
performance, e.g., the filtration efficiency of PM0.3 was
promoted from 59.38% for pure PLA to 94.38% after addition of 30 wt
% HABE at a moderate airflow capacity of 32 L/min and from 30.78 to
83.75% at the highest level of 85 L/min. It is of interest that the
pressure drop was significantly decreased, mainly arising from the
slip effect between the ultrafine nanofibers and conjugated microfibers.
The proposed combination of the nanostructured electret and the multistructuring
strategy offers the function integration of efficient filtration and
low resistance that are highly useful to pursue fully biodegradable
filters.
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