N95 decontamination protocols and
KN95 respirators have been described
as solutions to a lack of personal protective equipment. However,
there are a few material science studies that characterize the charge
distribution and physical changes accompanying disinfection treatments,
particularly heating. Here, we report the filtration efficiency, dipole
charge density, and fiber integrity of N95 and KN95 respirators before
and after various decontamination methods. We found that the filter
layers in N95 and KN95 respirators maintained their fiber integrity
without any deformations during disinfection. The filter layers of
N95 respirators were 8-fold thicker and had 2-fold higher dipole charge
density than that of KN95 respirators. Emergency Use Authorization
(EUA)-approved KN95 respirators showed filtration efficiencies as
high as N95 respirators. Interestingly, although there was a significant
drop in the dipole charge in both respirators during decontamination,
there was no remarkable decrease in the filtration efficiencies due
to mechanical filtration. Cotton and polyester face masks had a lower
filtration efficiency and lower dipole charge. In conclusion, a loss
of electrostatic charge does not directly correlate to the decreased
performance of either respirator.
This paper developed a comprehensive model which can fully explain the surface potential behavior of corona charged organic dielectric electrets. Compared to previous studies, both sides of the corona charged films were measured while they were grounded or free-standing. All films showed surface potential with the same magnitude, but opposite polarity on each side while they were measured with the other side grounded. This indicates that in contrast to the previous incomplete model, believing only the corona side containing injected charges, both sides should contain injected charges with the same magnitude but opposite polarity. This dipolar charge distribution is relatively stable and leads to a constant and controllable potential difference ΔV f between each side of the free-standing measured film. Interestingly, free-standing surface potential varied dramatically for films charged with the same parameters. This large variation is caused by the minor number of free charges, which is only ~0.1% of the corona induced dipolar charges. Therefore, in this model, dipolar charges control the surface potential difference between each side and the minor charges control the absolute value on a certain side. By manipulating them together, the surface potential on both sides can be precisely controlled.
As essential components in intelligent systems, printed soft electronics (PSEs) are playing crucial roles in public health, national security, and economics. Innovations in printing technologies are required to promote the broad application of high-performance PSEs at a low cost. However, current printing techniques are still facing long-lasting challenges in addressing the conflict between printing speed and performance. To overcome this challenge, we developed a new corona-enabled electrostatic printing (CEP) technique for ultra-fast (milliseconds) roll-to-roll (R2R) manufacturing of binder-free multifunctional e-skins. The printing capability and controllability of CEP were investigated through parametric studies and microstructure observation. The electric field generation, material transfer, and particle amount and size selecting mechanisms were numerically and experimentally studied. CEP printed graphene e-skins were demonstrated to possess outstanding strain sensing performance. The binder-free feature of the CEP-assembled networks enables them to provide pressure sensitivity as low as 2.5 Pa, and capability to detect acoustic signals of hundreds of hertz in frequency. Furthermore, the CEP technique was utilized to pattern different types of functional materials (e.g., graphene and thermochromic polymers) onto different substrates (e.g., tape and textile). Overall, this study demonstrated that CEP can be a novel contactless and ultrafast manufacturing platform compatible with R2R process for fabricating high-performance, scalable, and low-cost soft electronics.
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