The global need for clean water requires
sustainable technology
for purifying contaminated water. Highly efficient solar-driven photodegradation
is a sustainable strategy for wastewater treatment. In this work,
we demonstrate that the photodegradation efficiency of micropollutants
in water can be improved by ∼2–24 times by leveraging
polymeric microlenses (MLs). These microlenses (MLs) are fabricated
from the in situ polymerization of surface nanodroplets. We found
that photodegradation efficiency (η) in water correlates approximately
linearly with the sum of the intensity from all focal points of MLs,
although no difference in the photodegradation pathway is detected
from the chemical analysis of the byproducts. With the same overall
power over a given surface area, η is doubled by using ordered
ML arrays, compared to heterogeneous MLs on an unpatterned substrate.
A higher η from ML arrays may be attributed to a coupled effect
from the focal points on the same plane that creates high local concentrations
of active species to further speed up the rate of photodegradation.
As a proof-of-concept for MLs-enhanced water treatment, MLs were formed
on the inner wall of glass bottles that were used as containers for
water to be treated. Three representative micropollutants (norfloxacin,
sulfadiazine, and sulfamethoxazole) in the bottles functionalized
by MLs were photodegraded by 30%–170% faster than in normal
bottles. Our findings suggest that the MLs-enhanced photodegradation
may lead to a highly efficient solar water purification approach without
a large-sized solar collector. Such an approach may be particularly
suitable for portable transparent bottles in remote regions.
The structures of two new macrocyclic jatrophane diterpenoid esters from the whole herb of Euphorbia esula, were established as 11,14-epoxy-3beta,5alpha,7beta,8alpha,9alpha,15beta-hexaacetoxy-12-oxo-13alphaH-jatropha-6(17)-ene (1) and 1alpha,3beta-diacetoxy-5alpha,7beta-dibenzoyloxy-9,14-dioxo-11beta,12alpha-epoxy-2alpha,8alpha,15beta-trihydroxy-13betaH-jatropha-6(17)-ene (2) by a combination of 1D- and 2D-NMR techniques as well as UV, IR and mass spectral data. Bioassay evaluation of all isolates against the human tumor cell lines (B16, KB, SMMC and BGC) indicated that ester 2 was cytotoxic to B16 with the IC50 value being 1.81 microg/ml. In addition, the irritant activity assay indicated that both diterpenoids were inactive (ID(24)50 > 100 microg/ear).
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