Zhiwei Zhu scite author profile

Ultrasmall molybdenum sulfide nanoparticles with diameters of 1.47 AE 0.16 nm were fabricated from bulk MoS 2 by a combination of ultrasonication and centrifugation. The nanoparticles were then assembled on an Au surface to form a film with high electrocatalytic activity for hydrogen evolution reaction (HER). A Tafel slope of 69 mV per decade was measured for this film and the onset potential was estimated to be À0.09 V. The small loading (1.03 mg cm À2 ) and the high current density (0.92 mA cm À2 at h ¼ 0.15 V) demonstrated extremely high catalytic efficiency. X-ray photoelectron spectroscopic results revealed that the assembled nanoparticle film was sulfur enriched with abundant S edges and a structural rearrangement of the S rich particles might occur during the self-assembly process, resulting in significantly enhanced electrocatalytic activity for HER. Electrochemical impedance measurements suggested that the assembling process optimized the conductivity of the nanoparticle film, which contributed to the enhanced HER catalytic activity. Our research has provided a new way to synthesize active molybdenum sulfide nanoparticles for HER and a new approach to achieve enrichment of S edges on molybdenum sulfide, which might have potential use not only for electrocatalytic HER, but also for photoelectrocatalytic HER and plasmon-enhanced water splitting. Broader contextHydrogen produced by the water splitting process could potentially address the needs for the sustainable production of fuels in a manner that is renewable and carbon-free. However, cheap catalysts are required to overcome the large overpotential for hydrogen evolution reaction (HER) in an affordable manner. Recent studies have shown that sulfur edges of MoS 2 are quite active for HER. As a result, much effort has been focused on trying to acquire MoS 2 or MoS x nanomaterials with a plethora of sulfur edges. Here, we demonstrate a novel approach for synthesizing monodispersed molybdenum sulde nanoparticles with ultrasmall diameters and a new strategy for achieving enrichment of active S edges on molybdenum suldes by exploiting the covalent bonding of the nanocatalysts with the underlying gold electrode. The work is benecial not only for the design of highly efficient molybdenum sulde based HER catalysts but also for the synthesis of new catalysts for photoelectrocatalytic HER and plasmon-enhanced water splitting.

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Large-Scale Fabrication of Tower-like, Flower-like, and Tube-like ZnO Arrays by a Simple Chemical Solution Route

Wang

et al. 2004

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Large-scale arrayed ZnO crystals with a series of novel morphologies, including tower-like, flower-like, and tube-like samples, have been successfully fabricated by a simple aqueous solution route. The morphology and orientation of the obtained ZnO crystal arrays can be conveniently tailored by changing the reactants and experimental conditions. For example, the tower-like ZnO crystal arrays were obtained in a reaction solution system including zinc salt, ammonia, ammonium salt, and thiourea, and the orientation of these tower-like crystals could be controlled by the contents of these reactants. Flower-like ZnO arrays were obtained at lower temperatures, and tube-like ZnO arrays were obtained by ultrasonic pretreatment of the reaction system. The growth mechanism of the tower-like and tube-like ZnO crystals was investigated by FESEM. The results show that tower-like crystals grow layer by layer, while tube-like crystals grow from active nanowires. Ultrasonic pretreatment is proved to be effective in promoting the formation of active nuclei, which have important effects on the formation of the tube-like ZnO crystals. In addition, large-scale arrays of these ZnO crystals can be successfully synthesized onto various substrates such as amorphous glass, crystalline quartz, and PET. This implies this chemical method has a wide application in the fabrication of nano-/microscale devices.

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Biosensor Based on Ultrasmall MoS₂ Nanoparticles for Electrochemical Detection of H₂O₂ Released by Cells at the Nanomolar Level

et al. 2013

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Monodispersed surfactant-free MoS2 nanoparticles with sizes of less than 2 nm were prepared from bulk MoS2 by simple ultrasonication and gradient centrifugation. The ultrasmall MoS2 nanoparticles expose a large fraction of edge sites, along with their high surface area, which lead to attractive electrocatalytic activity for reduction of H2O2. An extremely sensitive H2O2 biosensor based on MoS2 nanoparticles with a real determination limit as low as 2.5 nM and wide linear range of 5 orders of magnitude was constructed. On the basis of this biosensor, the trace amount of H2O2 released from Raw 264.7 cells was successfully recorded, and an efficient glucose biosensor was also fabricated. Since H2O2 is a byproduct of many oxidative biological reactions, this work serves as a pathway for the application of MoS2 in the fields of electrochemical sensing and bioanalysis.

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High Symmetric 18-Facet Polyhedron Nanocrystals of Cu₇S₄ with a Hollow Nanocage

et al. 2005

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On the basis of Kirkendall Effect, high symmetric 18-facet polyhedral nanocrystals of Cu7S4 with a hollow nanocage could be converted from cubic nanocrystals of Cu2O in an aqueous media. The presence of organic additives makes the surface energy of {110} smaller than those of {100} and {111}. The growth of nanocrystals along the normal direction of highest energy surface {100} leads to the formation of a 18-facet polyhedron.

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Zhiwei Zhu

Enhanced electrocatalytic activity for hydrogen evolution reaction from self-assembled monodispersed molybdenum sulfidenanoparticles on an Au electrode

Large-Scale Fabrication of Tower-like, Flower-like, and Tube-like ZnO Arrays by a Simple Chemical Solution Route

Biosensor Based on Ultrasmall MoS₂ Nanoparticles for Electrochemical Detection of H₂O₂ Released by Cells at the Nanomolar Level

High Symmetric 18-Facet Polyhedron Nanocrystals of Cu₇S₄ with a Hollow Nanocage

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Zhiwei Zhu

Enhanced electrocatalytic activity for hydrogen evolution reaction from self-assembled monodispersed molybdenum sulfidenanoparticles on an Au electrode

Large-Scale Fabrication of Tower-like, Flower-like, and Tube-like ZnO Arrays by a Simple Chemical Solution Route

Biosensor Based on Ultrasmall MoS2 Nanoparticles for Electrochemical Detection of H2O2 Released by Cells at the Nanomolar Level

High Symmetric 18-Facet Polyhedron Nanocrystals of Cu7S4 with a Hollow Nanocage

Contact Info

Product

Resources

About

Biosensor Based on Ultrasmall MoS₂ Nanoparticles for Electrochemical Detection of H₂O₂ Released by Cells at the Nanomolar Level

High Symmetric 18-Facet Polyhedron Nanocrystals of Cu₇S₄ with a Hollow Nanocage