PdAualloy@ZnO CSNPs are prepared and evaluated for hydrogen detection with superior behavior with respect to pure ZnO. Improvement is attributed to .synergistically catalytic effects between Pd, Au and ZnO in PdAualloy@ZnO core–shell sensory system
Noble metal-based surface-enhanced Raman spectroscopy (SERS) has enabled the simple and efficient detection of trace-amount molecules via significant electromagnetic enhancements at hot spots. However, the small Raman cross-section of various analytes forces the use of a Raman reporter for specific surface functionalization, which is time-consuming and limited to low-molecular-weight analytes. To tackle these issues, a hybrid SERS substrate utilizing Ag as plasmonic structures and GaN as charge transfer enhancement centers is presented. By the conformal printing of Ag nanowires onto GaN nanopillars, a highly sensitive SERS substrate with excellent uniformity can be fabricated. As a result, remarkable SERS performance with a substrate enhancement factor of 1.4 × 10 11 at 10 fM for rhodamine 6G molecules with minimal spot variations can be realized. Furthermore, quantification and multiplexing capabilities without surface treatments are demonstrated by detecting harmful antibiotics in aqueous solutions. This work paves the way for the development of a highly sensitive SERS substrate by constructing complex metal-semiconductor architectures.
Recently,
various attempts have been made for light-to-fuels conversion,
often with limited performance. Herein we report active and lasting
three-factored hierarchical photocatalysts consisting of plasmon Au,
ceria semiconductor, and graphene conductor for hydrogen production.
The Au@CeO2/Gr2.0 entity (graphene outer shell
thickness of 2.0 nm) under visible-light irradiation exhibits a colossal
achievement (8.0 μmol mgcat
–1 h–1), which is
2.2- and 14.3-fold higher than those of binary Au@CeO2 and
free-standing CeO2 species, outperforming the currently
available catalysts. Yet, it delivers a high maximum quantum yield
efficiency of 38.4% at an incident wavelength of 560 nm. These improvements
are unambiguously attributed to three indispensable effects: (1) the
plasmon resonant energy is light-excited and transferred to produce
hot electrons localizing near the surface of Au@CeO2, where
(2) the high-surface-area Gr conductive shell will capture them to
direct hydrogen evolution reactions, and (3) the active graphene hybridized
on the defect-rich surface of Au@CeO2 favorably adsorbs
hydrogen atoms, which all bring up thorough insight into the working
of a ternary Au@CeO2/Gr catalyst system in terms of light-to-hydrogen
conversion.
Au nanoclusters (2.18 wt%) consisting of a few tens of atoms supported nitrogen-doped graphene deliver an impressive hydrogen evolution reaction rate of 3.16 μmol mgcat−1 h−1 under visible-light irradiation and a high maximum quantum yield of 14.3%.
Transition metal dichalcogenides (TMDs), transition metal carbides (TMCs), and transition metal oxides (TMOs) have been widely investigated for electrocatalytic applications owing to their abundant active sites, high stability, good conductivity, and various other fascinating properties. Therefore, the synthesis of composites of TMDs, TMCs, and TMOs is a new avenue for the preparation of efficient electrocatalysts. Herein, we propose a novel low-cost and facile method to prepare TMD–TMC–TMO nano-hollow spheres (WS2–WC–WO3 NH) as an efficient catalyst for the hydrogen evolution reaction (HER). The crystallinity, morphology, chemical bonding, and composition of the composite material were comprehensively investigated using X-ray diffraction, Raman spectroscopy, field emission scanning electron microscopy, and X-ray photoelectron spectroscopy. The results confirmed the successful synthesis of the WS2–WC–WO3 NH spheres. Interestingly, the presence of nitrogen significantly enhanced the electrical conductivity of the hybrid material, facilitating electron transfer during the catalytic process. As a result, the WS2–WC–WO3 NH hybrid exhibited better HER performance than the pure WS2 nanoflowers, which can be attributed to the synergistic effect of the W–S, W–C, and W–O bonding in the composite. Remarkably, the Tafel slope of the WS2–WC–WO3 NH spheres was 59 mV dec−1, which is significantly lower than that of the pure WS2 NFs (82 mV dec−1). The results also confirmed the unprecedented stability and superior electrocatalytic performance of the WS2–WC–WO3 NH spheres toward the HER, which opens new avenues for the preparation of low-cost and highly effective materials for energy conversion and storage applications.
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