In this work a Sulzer structured packing, Mellapak 250Y, was studied for applications in the field of absorption. A new model was proposed which makes it possible to estimate the packing surface that actually takes part in the process. In the course of these studies, new experimental data were obtained relating to the absorption of 1,t, t -trichloroethane using Genosorb 300, a mixture of polyethylene glycol dimethyl ethers produced by Hoechst S.p.A., as absorption liquid. The results obtained with the proposed model are in agreement both with the experimental measurements made in the course of the work and with experimental absorption measurements reported by other authors on water systems.
One of the major concerns in the COVID-19 pandemic is related to the possible transmission in poorly ventilated spaces of SARS-CoV-2 through aerosol microdroplets, which can remain in the air for long periods of time and be transmitted to others over distances >1 m. Cold atmospheric pressure plasmas can represent a promising solution, thanks to their ability in producing a blend of many reactive species, which can inactivate the airborne aerosolized microorganisms. In this study, a dielectric barrier discharge plasma source is used to directly inactivate suitably produced bioaerosols containing Staphylococcus epidermidis or purified SARS-CoV-2 RNA flowing through it. Results show that for low residence times (<0.2 s) in the plasma region a 3.7 log R on bacterial bioaerosol and degradation of viral RNA can be achieved. K E Y W O R D S bioaerosol, cold plasma, inactivation, indoor airborne transmission, SARS-CoV-2 Alina Bisag and Pasquale Isabelli contributed equally to this study.
The electrochemical
transformation of biomass-derived compounds
(e.g., aldehyde electroreduction to alcohols) is gaining increasing
interest due to the sustainability of this process that can be exploited
to produce value-added products from biowastes and renewable electricity.
In this framework, the electrochemical conversion of 5-hydroxymethylfurfural
(HMF) to 2,5-bis(hydroxymethyl)furan (BHMF) is studied. Nanostructured
Ag deposited on Cu is an active and selective electrocatalyst for
the formation of BHMF in basic media. However, this catalyst deserves
further research to elucidate the role of the morphology and size
of the coated particles in its performance as well as the actual catalyst
surface composition and its stability. Herein, Ag is coated on Cu
open-cell foams by electrodeposition and galvanic displacement to
generate different catalyst morphologies, deepening on the particle
growth mechanism, and the samples are compared with bare Ag and Cu
foams. The chemical–physical and electrochemical properties
of the as-prepared and spent catalysts are correlated to the electroactivity
in the HMF conversion and its selectivity toward the formation of
BHMF during electroreduction. AgCu bimetallic nanoparticles or dendrites
are formed on electrodeposited and displaced catalysts, respectively,
whose surface is Cu-enriched along with electrochemical tests. Both
types of bimetallic AgCu particles evidence a superior electroactive
surface area as well as an enhanced charge and mass transfer in comparison
with the bare Ag and Cu foams. These features together with a synergistic
role between Ag and Cu superficial active sites could be related to
the twofold enhanced selectivity of the Ag/Cu catalysts for the selective
conversion of HMF to BHMF, that is, >80% selectivity and ∼
100% conversion, and BHMF productivity values (0.206 and 0.280 mmol
cm
–2
h
–1
) ca. 1.5–3 times
higher than those previously reported.
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