Polymorphism and Structural Distortions of Mixed-Metal Oxide Photocatalysts Constructed with α-U3O8 Types of Layers

King, Nacole; Boltersdorf, Jonathan; Maggard, Paul A.; Wong‐Ng, W.

doi:10.3390/cryst7050145

Cited by 6 publications

(5 citation statements)

References 129 publications

(226 reference statements)

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“…The structure is comprised of layers of linearly-coordinated Cu(I) and octahedrally-coordinated Ta(V) cations that alternate with double layers of edge-and vertex-shared TaO 7 pentagonal bipyramids. The layers of pentagonal bipyramids, i.e., the TaO 7 in Figure 1b, are similar to those previously described in the structure of α-U 3 O 8 [24]. To probe the bulk and surface-level thermal stability of Cu3Ta7O19, the crystalli were heated in air at temperatures spanning the range of 350 °C to >550 °C.…”

Section: Bulk Phase Analysis and Thermal Stabilitymentioning

confidence: 63%

A Metastable p-Type Semiconductor as a Defect-Tolerant Photoelectrode

et al. 2021

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A p-type Cu3Ta7O19 semiconductor was synthesized using a CuCl flux-based approach and investigated for its crystalline structure and photoelectrochemical properties. The semiconductor was found to be metastable, i.e., thermodynamically unstable, and to slowly oxidize at its surfaces upon heating in air, yielding CuO as nano-sized islands. However, the bulk crystalline structure was maintained, with up to 50% Cu(I)-vacancies and a concomitant oxidation of the Cu(I) to Cu(II) cations within the structure. Thermogravimetric and magnetic susceptibility measurements showed the formation of increasing amounts of Cu(II) cations, according to the following reaction: Cu3Ta7O19 + x/2 O2 → Cu(3−x)Ta7O19 + x CuO (surface) (x = 0 to ~0.8). With minor amounts of surface oxidation, the cathodic photocurrents of the polycrystalline films increase significantly, from <0.1 mA cm−2 up to >0.5 mA cm−2, under visible-light irradiation (pH = 6.3; irradiant powder density of ~500 mW cm−2) at an applied bias of −0.6 V vs. SCE. Electronic structure calculations revealed that its defect tolerance arises from the antibonding nature of its valence band edge, with the formation of defect states in resonance with the valence band, rather than as mid-gap states that function as recombination centers. Thus, the metastable Cu(I)-containing semiconductor was demonstrated to possess a high defect tolerance, which facilitates its high cathodic photocurrents.

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Section: Bulk Phase Analysis and Thermal Stabilitymentioning

confidence: 63%

A Metastable p-Type Semiconductor as a Defect-Tolerant Photoelectrode

et al. 2021

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“…In the case of the binary oxide compound Ca 12 Al 14 O 33 , firing in a reducing atmosphere results in the removal of occluded oxygen atoms, replacing them with other atoms, molecules, or electrons, where the latter can alter the conduction from highly resistive to near-metallic. King et al [10] showed that mixed-metal oxide compounds, with the general formula A m+ ((n+1)/m) B (3n+1) O (8n+3) , phase transitions that occur from varying the temperature, the composition, or the chemical reactions, can result in structural and electronic distortions that impact the efficiency of the photocatalysis. Two of the papers reported the crystal structures of new compounds along with complementary property measurements.…”

Section: Discussionmentioning

confidence: 99%

“…In photoelectrochemical water splitting, the electricity used to produce the hydrogen is supplied by a renewable energy source (i.e., a photovoltaic system). In the paper presented by King et al [10], the authors review crystal structures having photocatalytical properties. This paper focuses on a series of mixed-metal oxide structures, based on the stacking of α-U 3 O 8 type pentagonal bipyramid layers, with the general formula A m+ ((n+1)/m) B (3n+1) O (8n+3) , where the A cation can be Ag, Bi, Ca, Cu, Ce, Dy, Eu, Gd K, La, Nd, Pb, Pr, Sr, or Y, the B cation is either Nb or Ta, and m = 1-3 and n = 1, 1.5, 2.…”

Section: Photocatalysis Materials Constructed Using α-U 3 O 8 Types Omentioning

confidence: 99%

Crystallography of Functional Materials

Wong‐Ng

Rawn

2017

Crystals

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Abstract:The goal of this special issue is to obtain new insights into the roles of crystallography in functional materials. This special issue consists of eight papers illustrating the structure and property relationships, as well as applications of selected classes of materials that deal with various aspects of functional materials, ranging from battery, magnetic, photocatalysis, and waveguide materials, to luminescent metal-organic frameworks and borates, semiconductors, and inorganic electrides. This issue provides further evidence of the importance of crystallography in understanding and improving various properties of functional materials, whether they are single crystals, bulk polycrystalline materials, or thin films.

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“…However, though the structural symmetry of orthorhombic KNbO 3 is lower than that of tetragonal KNbO 3 , it presents a better performance, probably due to better morphology, that is, the exposed facets and the associated electronic structure. In contrast, King et al have found that structure distortions lowering the symmetry have an influence on the photocatalytic performance, for example, for PbTa 4 O 11 with an out-of-plane distortion of the d 0 transition metal cation, an internal electric dipole can facilitate the separation of charge carriers (electron/hole), hindering the recombination and back-reaction [32]. Finally, Huang et al have reviewed synthesis methods for symmetry-breaking in multicomponent NPs, concluding that NPs with broken symmetry could be beneficial for various photocatalytic and electrocatalytic reactions resulting from: (i) arrangement of one-direction of charge migration, (ii) spatial separation of domains (prevention of reverse reactions), and (iii) synergism at the interface of different domains [33].…”

Section: Introductionmentioning

confidence: 95%

Does Symmetry Control Photocatalytic Activity of Titania-Based Photocatalysts?

et al. 2021

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Decahedral anatase particles (DAPs) have been prepared by the gas-phase method, characterized, and analyzed for property-governed photocatalytic activity. It has been found that depending on the reaction systems, different properties control the photocatalytic activity, that is, the particle aspect ratio, the density of electron traps and the morphology seem to be responsible for the efficiency of water oxidation, methanol dehydrogenation and oxidative decomposition of acetic acid, respectively. For the discussion on the dependence of the photocatalytic activity on the morphology and/or the symmetry other titania-based photocatalysts have also been analyzed, that is, octahedral anatase particles (OAP), commercial titania P25, inverse opal titania with and without incorporated gold NPs in void spaces and plasmonic photocatalysts (titania with deposits of gold). It has been concluded that though the morphology governs photocatalytic activity, the symmetry (despite its importance in many cases) rather does not control the photocatalytic performance.

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Polymorphism and Structural Distortions of Mixed-Metal Oxide Photocatalysts Constructed with α-U3O8 Types of Layers

Cited by 6 publications

References 129 publications

A Metastable p-Type Semiconductor as a Defect-Tolerant Photoelectrode

A Metastable p-Type Semiconductor as a Defect-Tolerant Photoelectrode

Crystallography of Functional Materials

Does Symmetry Control Photocatalytic Activity of Titania-Based Photocatalysts?

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