Solid Solutions Rb0.95NbxMo2–xO6.475–0.5x (x = 1.31–1.625) with Orthorhombic β-Pyrochlore Structure: Thermal Behavior and Electronic Structure of β-Pyrochlores Compounds Based on [Nb(Ta)/Mo] Octahedral Framework

Fukina, Diana G.; Сулейманов, Е. В.; Boryakov, A. V.; Zubkov, Sergei Yu; Усанов, Д. А.; Borisov, E. N.; Lyakaev, D. V.; Fomina, Lilia D

doi:10.1021/acs.inorgchem.0c01895

Cited by 16 publications

(14 citation statements)

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“…Since the ratio of atoms with oxidation states 5+ and 6+ differs from 1 : 1 (or 8 : 8 per unit cell), the partial loss of oxygen atoms is necessary to maintain the electroneutrality of the unit cell. As was shown for the orthorhombic phase Rb 0.95 Nb 1.375 Mo 0.625 O 5.79 , [4a] it is most likely that the oxygen deficiency is realized through the formation of defective [MoO 5 ] octahedra.…”

Section: Resultsmentioning

confidence: 79%

“…Previously, in the ternary system Rb 2 O‐2MoO 3 ‐Nb 2 O 5 we have obtained the Rb 0.95 Nb x Mo 2‐x O 6.475‐0.5x (x=1.31–1.663) solid solutions with an atypical orthorhombic ( Pnma ) β‐pyrochlore structure [4a] . The details of crystal and electronic structure have been investigated for a powder consisting of ∼20 μm single crystals with the composition Rb 0.95 Nb 1.375 Mo 0.625 O 5.79 .…”

Section: Resultsmentioning

confidence: 99%

“…Previously, we have obtained solid solutions with the structure of β‐pyrochlore Rb 0.95 Nb x Mo 2‐x O 6.475‐0.5x (x=1.31–1.663), which possess an orthorhombic symmetry ‐ atypical for this structural type, [4a] since the classical unit cell is described in terms of cubic symmetry. The typical synthetic conditions of polycrystalline powders is solid state synthesis using stoichiometric reagents mixture; however, it is possible to change the size particles and morphology varying method of synthesis.…”

Section: Introductionmentioning

confidence: 99%

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The Photocatalytic Oxidation Ability of Rb_0.9Nb_1.625Mo_0.375O_5.62 with Classic β‐Pyrochlore Structure

et al. 2022

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Previously the non-cubic β-pyrochlore polycrystalline compounds Rb 0.95 Nb x Mo 2-x O 6.475-0.5x (x = 1.31-1.663) have been obtained in the ternary system Rb 2 O-Nb 2 O 5 -2MoO 3 . However, using special synthesis condition leads to the formation of cubic Fd-3m β-pyrochlore Rb 0.9 Nb 1.625 Mo 0.375 O 5.62 with small size particles and surface area of 15 m 2 /g. The Rb 0.9 Nb 1.625 Mo 0.375 O 5.62 powder has been investigated by X-ray powder diffraction analysis and scanning electron microscopy with X-ray microanalysis. The crystal structure refinement has been performed using the Rietveld method. The electronic structure and optical band gap of Rb 0.9 Nb 1.625 Mo 0.375 O 5.62 have been studied in comparison to similar non-cubic composition Rb 0.95 Nb 1.625 Mo 0.375 O 5.66 . The photocatalytic properties of Rb 0.9 Nb 1.625 Mo 0.375 O 5.62 have been investigated on the example for dyes solution oxidation under UV irradiation. The dependence on the photocatalytic properties of dye type and catalyst mass has been studied. It has been observed that the main oxidative species for dye oxidation is hydroxyl radicals. The phase and composition stability of catalyst powder have been confirmed.

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Section: Resultsmentioning

confidence: 79%

Section: Resultsmentioning

confidence: 99%

Section: Introductionmentioning

confidence: 99%

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The Photocatalytic Oxidation Ability of Rb_0.9Nb_1.625Mo_0.375O_5.62 with Classic β‐Pyrochlore Structure

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“…Our calculated structural formula for β-pyrochlores is consistent with neutron and X-ray structural refinement of CsTe 2 O 5.75 , considering that A 4c = Cs; B 4c = Te(1); B 4a = Te(2) and Te(3); X 4c = O(1) and O(2); X 8d = O(3) and O(4). Another similar example of orthorhombic β-pyrochlores is solid solutions Rb 0.95 Nb x Mo 2– x O 6.475–0.5 x ( x = 1.310–1.625) . Orthorhombically distorted β-pyrochlore phases were also found in different fluorides (see for example refs and ).…”

Section: Resultsmentioning

confidence: 88%

“…Another similar example of orthorhombic β-pyrochlores is solid solutions Rb 0.95 Nb x Mo 2−x O 6.475−0.5x (x = 1.310−1.625). 134 Orthorhombically distorted β-pyrochlore phases were also found in different fluorides (see for example refs 135 and 136).…”

Section: ■ Results and Discussionmentioning

confidence: 99%

Structural Diversity of Ordered Pyrochlores

Таланов

2021

Chem. Mater.

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Pyrochlores belong to a numerous family of crystalline materials with a rich variety of technologically important functional properties and developed structural diversity of possible transformations including isosymmetric, reconstructive, and phase transitions of second order (and first order close to second order). Here, using a combination of group-theoretical and crystallographic analysis, we report a uniform classification of 343 types of possible ordered phases, which are theoretically derived from only one initial A 2 B 2 X 6 Y pyrochlore structure by different specific physical mechanisms (order parameters or its combinations) and show a hierarchical relationship between them. A symmetry analysis of the intrinsic relationships between structural degrees of freedom and atomic order in pyrochlore crystals made it possible to highlight six nominal classes of atomic order depending on the ordered sublattice, and by taking into account the role of the improper ordered parameters, only four classes remain: X, XY, ABX, and ABXY. For each of these abstract classes of atomic order the modified Barnighausen tree, illustrating the symmetry pathways of group−subgroup relation and participation of relevant order parameters, was constructed. Three fundamental structural features of the ordered pyrochlores have been established: (a) the impossibility of "pure" (not accompanied by atomic displacements) cation ordering at the A and B pyrochlore sublattices (16d and 16c Wyckoff positions, respectively); (b) the impossibility of "pure" ordering of anions at the X sublattice (48f Wyckoff position); (c) atomic ordering in the A sublattice which is always accompanied by atomic ordering in the B sublattice. A brief review of experimentally known ordered pyrochlores consistent with our structural predictions is given. Finally, the main directions of the theoretical results application including interpretation of the phase transition origins, experimental property predictions, the choice of a model for structural refinement or for materials design as a starting point for energy calculations, and a classification of the hierarchical relationship between phases are discussed. This study provides a symmetry guide for the extensive family of ordered pyrochlores and shows the origin of its structural diversity.

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Crystal Structure and Photocatalytic Properties of the CsV_0.625Te_1.375O₆ Mixed‐Valence β‐Pyrochlore Compound

et al. 2023

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A new β‐pyrochlore compound with complex composition of Cs(V3+0.0625V5+0.5625Te4+0.34375Te6+1.03125)O6 has been synthesized by a solid‐state reaction and characterized by single‐crystal X‐ray diffraction and thermal analysis. The compound possesses the typical cubic symmetry with space group , however some of the oxygen atoms shift from the special position 48 f to the general crystallographic positions 32e, 96 g and 96 h. This shift is caused by complex B‐site composition with mixed‐valence vanadium and tellurium atoms, especially the presence of the large Te4+ ion. The locations of the valence band and conduction band edges were determined experimentally under vacuum conditions by X‐ray photoelectron spectroscopy, UV‐visible and impedance spectroscopy and evaluated theoretically for water solutions. The photocatalytic ability of the compound under visible light irradiation was determined using the methylene blue decomposition process as an example. The nature of the active radical species and possible dye degradation pathway were suggested according to experimental data.

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Solid Solutions Rb_0.95Nb_xMo_2–xO_6.475–0.5x (x = 1.31–1.625) with Orthorhombic β-Pyrochlore Structure: Thermal Behavior and Electronic Structure of β-Pyrochlores Compounds Based on [Nb(Ta)/Mo] Octahedral Framework

Cited by 16 publications

References 41 publications

The Photocatalytic Oxidation Ability of Rb_0.9Nb_1.625Mo_0.375O_5.62 with Classic β‐Pyrochlore Structure

The Photocatalytic Oxidation Ability of Rb_0.9Nb_1.625Mo_0.375O_5.62 with Classic β‐Pyrochlore Structure

Structural Diversity of Ordered Pyrochlores

Crystal Structure and Photocatalytic Properties of the CsV_0.625Te_1.375O₆ Mixed‐Valence β‐Pyrochlore Compound

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Solid Solutions Rb0.95NbxMo2–xO6.475–0.5x (x = 1.31–1.625) with Orthorhombic β-Pyrochlore Structure: Thermal Behavior and Electronic Structure of β-Pyrochlores Compounds Based on [Nb(Ta)/Mo] Octahedral Framework

Cited by 16 publications

References 41 publications

The Photocatalytic Oxidation Ability of Rb0.9Nb1.625Mo0.375O5.62 with Classic β‐Pyrochlore Structure

The Photocatalytic Oxidation Ability of Rb0.9Nb1.625Mo0.375O5.62 with Classic β‐Pyrochlore Structure

Structural Diversity of Ordered Pyrochlores

Crystal Structure and Photocatalytic Properties of the CsV0.625Te1.375O6 Mixed‐Valence β‐Pyrochlore Compound

Contact Info

Product

Resources

About

Solid Solutions Rb_0.95Nb_xMo_2–xO_6.475–0.5x (x = 1.31–1.625) with Orthorhombic β-Pyrochlore Structure: Thermal Behavior and Electronic Structure of β-Pyrochlores Compounds Based on [Nb(Ta)/Mo] Octahedral Framework

The Photocatalytic Oxidation Ability of Rb_0.9Nb_1.625Mo_0.375O_5.62 with Classic β‐Pyrochlore Structure

The Photocatalytic Oxidation Ability of Rb_0.9Nb_1.625Mo_0.375O_5.62 with Classic β‐Pyrochlore Structure

Crystal Structure and Photocatalytic Properties of the CsV_0.625Te_1.375O₆ Mixed‐Valence β‐Pyrochlore Compound