A new class of metal-free heterojunction photocatalysts was prepared by wrapping reduced graphene oxide (RGO) and g-C3N4 (CN) sheets on crystals of cyclooctasulfur (α-S8). Two distinctive structures were fabricated by wrapping RGO and CN sheets in different orders. The first was RGO sheets sandwiched in heterojunction of CN sheets and α-S8 (i.e., CNRGOS8), while the second structure was the other way around (i.e., RGOCNS8). Both structures exhibited antibacterial activity under visible-light irradiation. CNRGOS8 showed stronger bacterial inactivation than RGOCNS8 in aerobic conditions. However, RGOCNS8 was more active than CNRGOS8 under anaerobic condition. A possible mechanism was proposed to explain the differences between photocatalytic oxidative inactivation and reductive inactivation. As a proof-of-concept, this work could offer new inroads into exploration and utilization of graphene sheets and g-C3N4 sheets cowrapped nanocomposites for environmental applications.
The
synthesis of hydrogen peroxide (H2O2)
from H2O and O2 by metal-free photocatalysts
(e.g., graphitic carbon nitride, C3N4) is a
potentially promising approach to generate H2O2. However, the photocatalytic H2O2 generation
activity of the pristine C3N4 in pure H2O is poor due to unpropitious rapid charge recombination and
unfavorable selectivity. Herein, we report a facile method to boost
the photocatalytic H2O2 production by grafting
cationic polyethylenimine (PEI) molecules onto C3N4. Experimental results and density functional theory (DFT)
calculations demonstrate PEI can tune the local electronic environment
of C3N4. The unique intermolecular electronic
interaction in PEI/C3N4 not only improves the
electron–hole separation but also promotes the two-electron
O2 reduction to H2O2 via the sequential
two-step single-electron reduction route. With the synergy of improved
charge separation and high selectivity of two-electron O2 reduction, PEI/C3N4 exhibits an unexpectedly
high H2O2 generation activity of 208.1 μmol
g–1 h–1, which is 25-fold higher
than that of pristine C3N4. This study establishes
a paradigm of tuning the electronic property of C3N4 via functional molecules for boosted photocatalysis activity
and selectivity.
Earth-abundant red phosphorus was found to exhibit remarkable efficiency to inactivate Escherichia coli K-12 under the full spectrum of visible light and even sunlight. The reactive oxygen species (•OH, •O2(-), H2O2), which were measured and identified to derive mainly from photogenerated electrons in the conduction band using fluorescent probes and scavengers, collectively contributed to the good performance of red phosphorus. Especially, the inactivated-membrane function enzymes were found to be associated with great loss of respiratory and ATP synthesis activity, the kinetics of which paralleled cell death and occurred much earlier than those of cytoplasmic proteins and chromosomal DNA. This indicated that the cell membrane was a vital first target for reactive oxygen species oxidation. The increased permeability of the cell membrane consequently accelerated intracellular protein carboxylation and DNA degradation to cause definite bacterial death. Microscopic analyses further confirmed the cell destruction process starting with the cell envelope and extending to the intracellular components. The red phosphorus still maintained good performance even after recycling through five reaction cycles. This work offers new insight into the exploration and use of an elemental photocatalyst for "green" environmental applications.
The
oxygen vacancy in MnO2 is normally proved as the
reactive site for the catalytic ozonation, and acquiring a highly
reactive crystal facet with abundant oxygen vacancy by facet engineering
is advisable for boosting the catalytic activity. In this study, three
facet-engineered α-MnO2 was prepared and successfully
utilized for catalytic ozonation toward an odorous CH3SH.
The as-synthesized 310-MnO2 exhibited superior activity
in catalytic ozonation of CH3SH than that of 110-MnO2 and 100-MnO2, which could achieve 100% removal
efficiency for 70 ppm of CH3SH within 20 min. The results
of XPS, Raman, H2-TPR, and DFT calculation all prove that
the (310) facets possess a higher surface energy than other facets
can feature the construction of oxygen vacancies, thus facilitating
the adsorption and activate O3 into intermediate peroxide
species (O2–/O2
2–)
and reactive oxygen species (•O2
–/1O2) for eliminating adjacent CH3SH. In situ diffuse reflectance infrared Fourier transform spectroscopy
(in situ DRIFTS) revealed that the CH3SH molecular was
chemisorbed on S atom to form CH3S–,
which was further converted into intermediate CH3SO3
– and finally oxidized into SO4
2– and CO3
2–/CO2 during the process. Attributed to the deep oxidation of CH3SH on 310-MnO2 via efficient cycling of active
oxygen vacancies, the lifetime of 310-MnO2 can be extended
to 2.5 h with limited loss of activity, while 110-MnO2 and
100-MnO2 were inactivated within 1 h. This study deepens
the comprehension of facet-engineering in MnO2 and presents
an efficient and portable catalyst to control odorous pollution.
In this study, Ag deposited three-dimensional MnO 2 porous hollow microspheres (Ag/MnO 2 PHMSs) with high dispersion of the atom level Ag species are first prepared by a novel method of redox precipitation. Due to the highly efficient utilization of downsized Ag nanoparticles, the optimal 0.3% Ag/MnO 2 PHMSs can completely degrade 70 ppm CH 3 SH within 600 s, much higher than that of MnO 2 PHMSs (79%). Additionally, the catalyst retains longterm stability and can be regenerated to its initial activity through regeneration with ethanol and HCl. The results of characterization of Ag/MnO 2 PHMSs and catalytic performance tests clearly demonstrate that the proper amount of Ag incorporation not only facilitates the chemi-adsorption but also induces more formation of vacancy oxygen (O v ) and lattice oxygen (O L ) in MnO 2 as well as Ag species as activation sites to collectively favor the catalytic ozonation of CH 3 SH. Ag/MnO 2 PHMSs can efficiently transform CH 3 SH into CH 3 SAg/CH 3 S-SCH 3 and then oxidize them into SO 4 2− and CO 2 as evidenced by in situ diffuse reflectance infrared Fourier transform spectroscopy. Meanwhile, electron paramagnetic resonance and scavenger tests indicate that •OH and 1 O 2 are the primary reactive species rather than surface atomic oxygen species contributing to CH 3 SH removal over Ag/MnO 2 PHMSs. This work presents an efficient catalyst of single atom Ag incorporated MnO 2 PHMSs to control air pollution.
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