W and two-dimensional WO<sub>3</sub>/W nanocrystals produced by controlled self-sustaining reduction of sodium tungstate

Manukyan, Khachatur V.; Voskanyan, Albert A.; Rouvimov, Sergei; Mukasyan, Alexander S.; Kharatyan, S. L.

doi:10.1557/jmr.2013.234

Cited by 5 publications

(4 citation statements)

References 38 publications

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“…In some modeled experiments, combustion of gels is performed in a wedge of a massive copper block. While the combustion wave propagates along the wedge, the heat losses increase to a point, leading to the arrest of the reaction front. , The layer-by-layer studies of the quenched sample allow us to determine the dynamics of microstructural transformation in the combustion wave.…”

Section: Experimental Methodsmentioning

confidence: 99%

Solution Combustion Synthesis of Nano-Crystalline Metallic Materials: Mechanistic Studies

et al. 2013

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The mechanism of structural transformation during combustion of nickel nitrate (oxidizer)−glycine (fuel) system is investigated by using different in situ techniques, including time-resolved X-ray diffraction (TRXRD), thermogravimetric analysis (TGA), differential scanning calorimetry (DSC) with dynamic mass spectrometry (MS), and high-speed infrared thermal imaging. It is shown that for initial compositions with a relatively large fuel-to-oxidizer ratio (φ), pure Ni phase forms directly in the combustion front. For fuel-lean conditions, only NiO phase can be detected. Analysis of the obtained data, including transmission and scanning electron microscopy (TEM−SEM) studies of the quenched reaction fronts, allows us to suggest the intrinsic mechanism of pure metal formation in the investigated system. It is shown that the combustion front propagates because of the reaction between N 2 O and NH 3 , which are the products of decomposition of the oxidizer and fuel. The excess of NH 3 gas produced in fuel-rich conditions rapidly (<0.2 s) reduces nickel oxide to pure metal in the reaction front.

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Section: Experimental Methodsmentioning

confidence: 99%

Solution Combustion Synthesis of Nano-Crystalline Metallic Materials: Mechanistic Studies

et al. 2013

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“…32 Perry et al 33 have synthesized nanoscale WO 3 •H 2 O platelets by a crash precipitation method. Manukyan et al 34 have reported that WO 3 •H 2 O nanosheets can be obtained by acid treatment of CaWO 4 sheets, which were produced by controlled selfsustaining reduction of Na 2 WO 4 at room temperature. However, the morphologies of the platelets and the nanosheets obtained by these two methods are not uniform.…”

Section: Introductionmentioning

confidence: 99%

Facile Fabrication of WO₃ Nanoplates Thin Films with Dominant Crystal Facet of (002) for Water Splitting

Zheng

Song

Hong

et al. 2014

Crystal Growth & Design

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Single crystalline orthorhombic phase tungsten trioxide monohydrate (O-WO 3 •H 2 O, space group: Pmnb) nanoplates with a clear morphology and uniform size distribution have been synthesized by the hydrothermal method and fabricated on the surface of fluorine doped tin oxide (FTO) coated glass substrates with selective exposure of the crystal facet by the finger rubbing method. The rubbing method can easily arrange the O-WO 3 •H 2 O nanoplates along the (020) facet on the FTO substrate. The O-WO 3 •H 2 O nanoplate can be converted to monoclinic phase WO 3 (γ-WO 3 , space group: P21/n) with dominant crystal facet of (002) without destroying the plate structure. Crystal morphologies, structures, and components of the powders and films have been determined by scanning electron microscopy, transmission electron microscopy, X-ray diffraction, Raman, X-ray photoelectron spectroscopy, etc. The band gap energies of the O-WO 3 •H 2 O and γ-WO 3 nanoplates were determined as ca. 2.26 and 2.49 eV, respectively. Photoelectrochemical properties of the films with (002) dominant crystal facet have also been checked for discussion of further application in water oxidation. The advantage of (002) facet dominant film was investigated by comparing to one spin-coated γ-WO 3 thin film with the same thickness via photoelectrochemical characterizations such as photocurrent, incident photon to current efficiency, and electrochemical impedance spectroscopy.

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“…The lattice d-spacings of 0.20 and 0.27 nm corresponded to the crystal plane of MnTiO 3 [1 1 0] 47 and TiO 2 [1 0 1] 47 , respectively. The WO 3 /W had a lattice d-spacing of 0.21 nm, relating to the lattice plane of WO 3 /W [2 0 1] 48 . The Mn 2 O 3 and Mn 3 O 4 had a lattice d-spacing of 0.23 nm, corresponding to the crystal plane of Mn 2 O 3 [1 1 1] 49 and Mn 3 O 4 [0 1 0] 50 .…”

Section: Resultsmentioning

confidence: 99%

Oxidative coupling of methane—comparisons of MnTiO3–Na2WO4 and MnOx–TiO2–Na2WO4 catalysts on different silica supports

Tiyatha

Chukeaw

Sringam

et al. 2022

Sci Rep

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The oxidative coupling of methane (OCM) converts CH4 to value-added chemicals (C2+), such as olefins and paraffin. For a series of MnTiO3-Na2WO4 (MnTiO3-NW) and MnOx-TiO2-Na2WO4 (Mn-Ti-NW), the effect of loading of MnTiO3 or MnOx-TiO2, respectively, on two different supports (sol–gel SiO2 (SG) and commercial fumed SiO2 (CS)) was examined. The catalyst with the highest C2+ yield (21.6% with 60.8% C2+ selectivity and 35.6% CH4 conversion) was 10 wt% MnTiO3-NW/SG with an olefins/paraffin ratio of 2.2. The catalyst surfaces with low oxygen-binding energies were associated with high CH4 conversion. Stability tests conducted for over 24 h revealed that SG-supported catalysts were more durable than those on CS because the active phase (especially Na2WO4) was more stable in SG than in CS. With the use of SG, the activity of MnTiO3-NW was not substantially different from that of Mn-Ti-NW, especially at high metal loading.

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W and two-dimensional WO₃/W nanocrystals produced by controlled self-sustaining reduction of sodium tungstate

Cited by 5 publications

References 38 publications

Solution Combustion Synthesis of Nano-Crystalline Metallic Materials: Mechanistic Studies

Solution Combustion Synthesis of Nano-Crystalline Metallic Materials: Mechanistic Studies

Facile Fabrication of WO₃ Nanoplates Thin Films with Dominant Crystal Facet of (002) for Water Splitting

Oxidative coupling of methane—comparisons of MnTiO3–Na2WO4 and MnOx–TiO2–Na2WO4 catalysts on different silica supports

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W and two-dimensional WO3/W nanocrystals produced by controlled self-sustaining reduction of sodium tungstate

Cited by 5 publications

References 38 publications

Solution Combustion Synthesis of Nano-Crystalline Metallic Materials: Mechanistic Studies

Solution Combustion Synthesis of Nano-Crystalline Metallic Materials: Mechanistic Studies

Facile Fabrication of WO3 Nanoplates Thin Films with Dominant Crystal Facet of (002) for Water Splitting

Oxidative coupling of methane—comparisons of MnTiO3–Na2WO4 and MnOx–TiO2–Na2WO4 catalysts on different silica supports

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W and two-dimensional WO₃/W nanocrystals produced by controlled self-sustaining reduction of sodium tungstate

Facile Fabrication of WO₃ Nanoplates Thin Films with Dominant Crystal Facet of (002) for Water Splitting