Stable photocatalysts
with excellent optical adsorption and low
reaction barrier are the key for the water splitting. Here, we find
that a two-dimensional Janus WSSe monolayer possesses the compelling
photocatalytic properties from density functional theory simulations,
which can be well modulated with strain deformation. Comprehensive
investigations indicate that the Janus material not only exhibits
strong optical absorbance in the visible spectrum, suitable band edge
potentials, high carrier separation, and transfer efficiency but also
has adequate driving forces of photoexcited carrier for water redox
reaction and good resistance against photoinduced corrosion. Janus
WSSe is therefore predicted to be a promising photocatalyst for water
splitting. Moreover, we also find that tensile strains could further
improve the photocatalytic performance for water splitting by effectively
increasing the energy conversion efficiency and reducing the exciton
binding energy. Our results not only predict a photocatalyst, which
can utilize the visible light for overall water splitting, but also
propose an effective path to extend the absorption spectra and raise
the photocatalytic efficiency.
Photocatalytic water splitting is
a promising technology to solve the energy crisis and provide renewable
and clean energies. Recently, although numerous 2D materials have
been proposed as the photocatalytic candidates, the strategies to
effectively modulate photocatalytic reactions and conversion efficiency
are still lacking. Herein, based on first-principles calculations,
we show that the photocatalytic activities and energy conversion efficiency
can be well tuned by ferroelectric–paraelectric phase transition
of a AgBiP2Se6 monolayer. It is found that the
AgBiP2Se6 monolayer has a higher potential and
driving forces of photogenerated holes for water oxidation in the
ferroelectric phase, but higher corresponding values of photogenerated
electrons for the hydrogen reduction reaction in the paraelectric
phase. Besides, the solar-to-hydrogen energy conversion efficiency
is also tunable with the phase transition; it is up to 10.04% at the
ferroelectric phase due to the better carrier utilization, but only
6.66% at the paraelectric phase. Moreover, the exciton binding energy
is always smaller in the paraelectric state than that in the ferroelectric
state, indicating that the ferroelectric switch could also make a
directional adjustment to the photoexcited carrier separation. Our
theoretical investigation not only reveals the importance of ferroelectric
polarization on water splitting, but also opens an avenue to modify
the photocatalytic properties of 2D ferroelectric materials via a
ferroelectric switch.
Shewanella oneidensis is an important model organism for its versatility of anaerobic respiration. CymA, a cytoplasmic membrane-bound tetraheme c-type cytochrome, plays a central role in anaerobic respiration by transferring electrons from the quinone pool to a variety of terminal reductases. Although loss of CymA results in defect in respiration of many electron acceptors (EAs), a significant share of the capacity remains in general. In this study, we adopted a transposon random mutagenesis method in a cymA null mutant to identify substituent(s) of CymA with respect to nitrite and nitrate respiration. A total of 87 insertion mutants, whose ability to reduce nitrite was further impaired, were obtained. Among the interrupted genes, the petABC operon appeared to be the most likely candidate given the involvement of the cytochrome bc1 complex that it encodes in electron transport. Subsequent analyses not only confirmed that the complex and CymA were indeed functionally overlapping in nitrate/nitrite respiration but also revealed that both proteins were able to draw electrons from ubiquinone and menaquinone. Furthermore, we found that expression of the bc1 complex was affected by oxygen but not nitrate or nitrite and by global regulators ArcA and Crp in an indirect manner.
Efficient and selective CO2 electroreduction into chemical fuels promises to alleviate environmental pollution and energy crisis, but it relies on catalysts with controllable product selectivity and reaction path. Here, by means of first-principles calculations, we identify six ferroelectric catalysts comprising transition-metal atoms anchored on In2Se3 monolayer, whose catalytic performance can be controlled by ferroelectric switching based on adjusted d-band center and occupation of supported metal atoms. The polarization dependent activation allows effective control of the limiting potential of CO2 reduction on TM@In2Se3 (TM = Ni, Pd, Rh, Nb, and Re) as well as the reaction paths and final products on Nb@In2Se3 and Re@In2Se3. Interestingly, the ferroelectric switching can even reactivate the stuck catalytic CO2 reduction on Zr@In2Se3. The fairly low limiting potential and the unique ferroelectric controllable CO2 catalytic performance on atomically dispersed transition-metals on In2Se3 clearly distinguish them from traditional single atom catalysts, and open an avenue toward improving catalytic activity and selectivity for efficient and controllable electrochemical CO2 reduction reaction.
Janus two-dimensional (2D) materials, referring to the layers with different surfaces, have attracted intensive research interest due to the unique properties induced by symmetry breaking, and promising applications in energy conversion. Based on the successful experimental synthesis of Janus transition metal dichalcogenides (TMDC), here we present a review on their potential application in photocatalytic overall water splitting, from the perspectives of the latest theoretical and experimental progress. Four aspects which are related to photocatalytic reaction, including the adsorption of water molecules, utilization of sunlight, charge separation and transport, and surface chemical reactions have been discussed, and it is concluded that the Janus structures have better performances than symmetric TMDCs. At the end of this review, we raise further challenges and possible future research directions for Janus 2D materials as water-splitting photocatalysts.
SummaryAs a most conserved complex molecular machine made up of a large number of structural subunits, the flagellum is under tight regulation by hierarchical arrangements. Although variations in polar flagellar systems are found, most of them are restricted to multiple-copy components, such as flagellins and stators. Therefore, these features are regarded to be peripheral relative to the comprehensive conservation. In this study, however, we present evidence to show that the difference in highly conserved polar flagellar systems can be surprisingly profound, even at the heart of the classical regulatory hierarchy. In Gram-negative Shewanella oneidensis, twocomponent system FlrBC, whose counterpart is essential for flagellar biosynthesis and motility by directly controlling expression of class III genes in polarly flagellated bacteria such as Vibrio cholerae, is dispensable for the process. The system directly controls expression of the flaA gene, encoding a flagellin of weak motility. We further show that the ratio of two flagellins, FlaA and FlaB, determines motility of a flagellum. More strikingly, overproduction of FlrC results in a peritrichously multi-flagellated phenotype, and FlrC is likely to function as an activator in its unphosphorylated form for transcription of the flaA gene, contrasting the previously characterized counterpart.
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