Novel entropy-stabilized fluorite oxides with multifunctional properties

Kumar, Ashutosh; Bérardan, David; Brisset, François; Dragoé, Diana; Dragoe, Nita

doi:10.1039/d3ta02124f

Cited by 10 publications

(2 citation statements)

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“…Kumar and co-workers introduced a series of innovative entropy-stabilized fluorite oxides. 133 They studied in more detail the temperature-dependent phase transitions of the fluorite oxides. A reversible transition between multiple phases and single phase was demonstrated through cyclic heat treatments, affirming that the thermodynamic stability is governed by configurational entropy.…”

Section: High-entropy Rare Earth Oxidesmentioning

confidence: 99%

High-entropy rare earth materials: synthesis, application and outlook

Fu,

Jiang,

Zhang

et al. 2024

Chem. Soc. Rev.

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Section: High-entropy Rare Earth Oxidesmentioning

confidence: 99%

High-entropy rare earth materials: synthesis, application and outlook

Fu,

Jiang,

Zhang

et al. 2024

Chem. Soc. Rev.

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“…Rock salt high-entropy oxides (HEOs), consisting of five or more equal molar metal cations, were first reported by Rost in 2015 . It is well established that HEOs have unique characteristics (such as large designing space, adjustable compositions, synergistic effect, multiple reactive sites, high durability, and low cost). − In particular, the catalytic properties of HEOs attract significant attention as they offer tremendous potential in alcohol oxidation reactions. Hence, a bloom of HEOs with various structures, for example, fluorite, perovskite, and spinel structures, are widely witnessed in applications of lithium-ion batteries, catalysts, dielectric materials, and energy storage. , At present, HEOs have been successfully fabricated by solid-state reaction, magnetron sputtering, thermal decomposition, nebulized spray pyrolysis, flame spray pyrolysis, hydrothermal, solution combustion, and coprecipitation .…”

Section: Introductionmentioning

confidence: 99%

Defect Engineering of High-Entropy Oxides for Superior Catalytic Oxidation Performance

Zhang,

Deng,

Chen

et al. 2023

ACS Appl. Mater. Interfaces

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High-entropy oxides (HEOs) are crucial in various fields (power storage/conversion, electronic devices, and catalysis) owing to their adjustable structural characteristics, fabulous stability, and massive components. However, the current strategies for synthesizing HEOs suffer from low surface area and limited active sites. Herein, we present a salt-assisted strategy with remarkable universality for the preparation of HEOs with high surface area [e.g., HP-(FeCrCoNiCu) x O y : 59 m 2 /g, HP-(ZnMgNiCuCo) x O y : 49 m 2 /g, and HP-(CrMnFeNiZn) x O y : 11 m 2 /g], where HP means high porosity. Especially, HP-(FeCrCoNiCu) x O y with rich-oxygen vacancies promotes catalytic efficiency for hydrocarbon and alcohol oxidation owing to its hierarchical texture and massive oxygen vacancies. Furthermore, density functional theory is utilized to well illustrate the relationship of the structure and catalytic efficiency within the catalysts. This work offers realistic pathway for the large-scale application of HEOs in catalytic areas.

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Thermoelectric Properties of High‐Entropy Wolframite Oxide: (CoCuNiFeZn)_1−xGa_xWO₄

Kumar,

Moll,

Mouhamadsiradjoudine

et al. 2023

Physica Rapid Research Ltrs

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Herein, the synthesis of high‐entropy wolframite oxide (CoCuNiFeZn)1‐xGaxWO4 through standard solid‐state route followed by spark plasma sintering and their structural, microstructural, and thermoelectric (TE) properties are investigated. X‐ray diffraction pattern followed by patterns matching refinement shows a monoclinic structure with the volume of the unit cell decreasing with increasing Ga content. The optical bandgap for these oxides shows a cocktail effect in high‐entropy configuration. The Seebeck coefficient indicates electrons as dominating charge carriers with a nondegenerate behavior. The electrical resistivity decreases with increasing temperature depicting a semiconducting nature. Thermal conductivity in high‐entropy samples (κ ≈ 2.1 W m−1 K−1 @ 300 K) is significantly lower as compared to MgWO4 (κ ≈ 11.5 W m−1 K−1 @ 300 K), which can be explained by the strong phonon scattering due to large lattice disorder in high‐entropy configuration. The TE figure of merit zT increases with Ga doping via modifying all three TE parameters positively.

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Novel entropy-stabilized fluorite oxides with multifunctional properties

Abstract: Development of new high-entropy oxides having configurational entropy dominating the phase stability has become a hot topic since the discovery of rock salt structure entropy-stabilized (MgCoNiCuZn)O in 2015. Herein, we...

Cited by 10 publications

References 56 publications

High-entropy rare earth materials: synthesis, application and outlook

High-entropy rare earth materials: synthesis, application and outlook

Defect Engineering of High-Entropy Oxides for Superior Catalytic Oxidation Performance

Thermoelectric Properties of High‐Entropy Wolframite Oxide: (CoCuNiFeZn)_1−xGa_xWO₄

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Novel entropy-stabilized fluorite oxides with multifunctional properties

Abstract: Development of new high-entropy oxides having configurational entropy dominating the phase stability has become a hot topic since the discovery of rock salt structure entropy-stabilized (MgCoNiCuZn)O in 2015. Herein, we...

Cited by 10 publications

References 56 publications

High-entropy rare earth materials: synthesis, application and outlook

High-entropy rare earth materials: synthesis, application and outlook

Defect Engineering of High-Entropy Oxides for Superior Catalytic Oxidation Performance

Thermoelectric Properties of High‐Entropy Wolframite Oxide: (CoCuNiFeZn)1−xGaxWO4

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Product

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Thermoelectric Properties of High‐Entropy Wolframite Oxide: (CoCuNiFeZn)_1−xGa_xWO₄