Perovskite Structure Compounds

Shimakawa, Yuichi

doi:10.1002/9783527691036.hsscvol1014

Cited by 7 publications

(10 citation statements)

References 119 publications

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“…Oxynitrides are attracting attention as promising white LED phosphors, photocatalysts, and dielectric materials. − However, the use of oxynitride perovskites is very challenging because their properties vary upon substituting their anions or cations . SrTaO 2 N crystallizes in the I 4/ mcm space group with a = 0.569411(7) nm and c = 0.80658(2) nm .…”

Section: Introductionmentioning

confidence: 99%

Intergrowth between the Oxynitride Perovskite SrTaO₂N and the Ruddlesden–Popper Phase Sr₂TaO₃N

et al. 2018

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Strontium tantalum oxynitrides were prepared within the nominal composition range of 1.0 ≤ x ≤ 2.0, where x = Sr/Ta atomic ratio. A gradual structural transition was observed between the perovskite SrTaON and the Ruddlesden-Popper phase SrTaON with increasing SrO content. X-ray diffraction analyses showed that a single-phase perovskite was obtained up to x = 1.1, after which SrTaON gradually appeared at x ≥ 1.25. High-resolution scanning transmission electron microscopy observations identified the gradual intergrowth of a Ruddlesden-Popper SrTaON type planar structure interwoven with the perovskite crystal lattice upon increasing x. The crystal lattice at x = 1.4 was highly defective and consisted primarily of perovskite intergrown with a large amount of the Ruddlesden-Popper phase structure. This Ruddlesden-Popper phase layer intergrowth is a characteristic of an oxynitride perovskite rather than the Ruddlesden-Popper defects previously reported in oxide perovskites. Partial substitution of Ta with Sr was also evident in this perovskite lattice. Just below x = 2, a perovskite-type structure was intergrown as defects in the Ruddlesden-Popper SrTaON. Characterization of SrTaON in ambient air was challenging due to its moisture sensitivity. Thermal analysis demonstrated that this material was relatively stable up to approximately 1400 °C in comparison with SrTaON perovskite, especially under nitrogen. SrTaON could keep its structure in a sealed tube, and some amount of SrCO was observed in XRD after 10 days of exposure to 75% relative humidity under prior ambient conditions. A compact of this material had a relative density of 96% after sintering at 1400 °C under 0.2 MPa of nitrogen, even though a drastic loss of nitrogen was previously reported for a SrTaON perovskite under these same conditions. Postammonolysis of the SrTaON ceramics was not required prior to studying its dielectric behavior. This is in contrast to the SrTaON perovskite, which requires postammonolysis to recover its stoichiometric composition and electrical insulating properties.

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Section: Introductionmentioning

confidence: 99%

Intergrowth between the Oxynitride Perovskite SrTaO₂N and the Ruddlesden–Popper Phase Sr₂TaO₃N

et al. 2018

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“…Having a closer look at the iconic material class of perovskites, it is interesting to look for correlations between tilt systems and complexity as represented by I G . For the classification of perovskite tilts after the Glazer (1972) notation we would like to refer to some insightful book chapters and reviews (Shimakawa, 2017;Woodward, 1997).…”

Section: Perovskite Tilt Systemsmentioning

confidence: 99%

crystIT: Complexity and Configurational Entropy of Crystal Structures via Information Theory

Kaußler¹,

Kieslich

2020

Preprint

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<div>The information content of a crystal structure as conceived by information theory has recently proved as an intriguing approach to calculate the complexity of a crystal structure within a consistent concept. Given the relatively young nature of the field, theory development is still at the core of on-going research efforts. In this work we provide an update to the current theory, improving the formulas that evaluation of crystal structures with partial occupancies as frequently found in disordered system is feasible. To encourage wider application and further theory development we incorporate the updated formulas in crystIT (crystal structure & Information Theory), an open-source python-based program that allows for calculating various complexity measures of crystal structures based on a standardized *.cif file.</div>

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“…In this aspect, the probability of identifying materials with the desired structures and properties is higher among the structural families that are flexible in terms of accommodating a wide range of cations and anions. For example, inorganic solids belonging to the families of perovskites and layered perovskites have often proven to be the most suitable functional materials because they exhibit several interesting physical properties such as conducting, superconducting, thermoelectric, magnetic, dielectric, ferroelectric, etc. − Particularly, among the layered perovskites, the families of Aurivillius oxides (AV; (Bi 2 O 2 )[A n –1 B n O 3 n +1 ]), , Ruddlesden–Popper oxides (RP; A′ 2 [A n –1 B n O 3 n +1 ]), , and Dion–Jacobson series of oxides (DJ; A′[A n –1 B n O 3 n +1 ]) − have widely attracted the attention of researchers. − All of these layered perovskites possess the common perovskite blocks [A n –1 B n O 3 n +1 ], with n being the number of BO 6 octahedra representing the thickness of the perovskite slabs where A represents the cations (e.g., Ca 2+ , Sr 2+ , La 3+ , and Bi 3+ ) in the perovskite blocks. A′ (Li, Na, K, Rb, and Cs) ions in RP and DJ oxides represent the interlayer cations.…”

Section: Introductionmentioning

confidence: 99%

“…Commonly, the corner-linked BO 6 octahedra in many perovskites (ABO 3 ) undergo certain rotations and tilts to stabilize the A cations that are smaller in size with a reduction in the symmetry to the orthorhombic structure (e.g., CaTiO 3 , with space group Pbnm ). The overall tilts and distortions based on their directions and magnitudes, in turn, result in individual centrosymmetric or NCS space groups and crystallographic structures in the ABO 3 perovskites. − In the case of layered perovskites, the combination of octahedral rotations in the x and y axes along with that in the z axis results in displacement of the A cation in the perovskite blocks [A n –1 B n O 3 n +1 ]. The collective octahedral rotations and A-cation displacements prohibiting the formation of structures with inversion symmetry have been explained in detail in several of the layered perovskites. , Topochemical fluorination of RP n = 2 members (La 3 Ni 2 O 7 ) was shown by Hayward et al to enhance the structural distortions leading to the formation of NCS structures (La 3 Ni 2 O 5.5 F 3.5 ).…”

Section: Introductionmentioning

confidence: 99%

“…Our interest has been to explore the formation of layered perovskites by varying the A cations in the DJ-based layered perovskite blocks [A n –1 B n O 3 n +1 ]. Even a small mismatch in the sizes of the A cations to the sizes of the B cations resulted in distortions that are commonly referred to as chemical pressure in the ABO 3 perovskites and are responsible for the significant changes in the physical properties . Toward this goal, first, we envisaged the incorporation of a d 10 ion such as Cd 2+ in the A cationic sites, while keeping a d 0 ion (Nb 5+ ) in the B cationic sites of the DJ n = 3 layered perovskites A′[A n –1 B n O 3 n +1 ] (A′ = Rb, Cs).…”

Section: Introductionmentioning

confidence: 99%

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Synergistic Influence of d⁰ (Nb⁵⁺) and d¹⁰ (Cd²⁺) Cations in Stabilizing Noncentrosymmetric Dion–Jacobson Layered Perovskites, A′Cd₂Nb₃O₁₀ (A′ = Rb, Cs)

2020

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New Dion−Jacobson (n = 3) layered perovskites, A′Cd 2 Nb 3 O 10 (A′ = Rb, Cs), have been synthesized by a solid-state method. Powder X-ray diffraction measurements confirm the noncentrosymmetric orthorhombic (space group Ima2) structures for both rubidium-and cesium-containing layered oxides. The distorted octahedral coordination of the d 0 metal cations (Nb 5+ ) coupled with the increased covalency in the lattice by the introduction of d 10 metal cations (Cd 2+ ) is responsible for the acentric structures. The resulting second-harmonicgeneration (SHG) efficiencies of the polycrystalline samples (size 45−63 μm) using 1064 nm radiation reveal comparable values for CsCd 2 Nb 3 O 10 and nearly 5 times higher output values for RbCd 2 Nb 3 O 10 with respect to potassium dihydrogen phosphate. These structures were further confirmed from transmission electron microscopy and Raman spectroscopy measurements. The optical characteristics show interesting variations to the expected photocatalytic activities. Ion-exchange reactions result in the synthesis of proton-and lithium-containing oxides, which are otherwise inaccessible by direct solid-state reactions. The mobilities of the interlayer ions have also been confirmed by ionic conductivity measurements.

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Perovskite Structure Compounds

Cited by 7 publications

References 119 publications

Intergrowth between the Oxynitride Perovskite SrTaO₂N and the Ruddlesden–Popper Phase Sr₂TaO₃N

Intergrowth between the Oxynitride Perovskite SrTaO₂N and the Ruddlesden–Popper Phase Sr₂TaO₃N

crystIT: Complexity and Configurational Entropy of Crystal Structures via Information Theory

Synergistic Influence of d⁰ (Nb⁵⁺) and d¹⁰ (Cd²⁺) Cations in Stabilizing Noncentrosymmetric Dion–Jacobson Layered Perovskites, A′Cd₂Nb₃O₁₀ (A′ = Rb, Cs)

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Perovskite Structure Compounds

Cited by 7 publications

References 119 publications

Intergrowth between the Oxynitride Perovskite SrTaO2N and the Ruddlesden–Popper Phase Sr2TaO3N

Intergrowth between the Oxynitride Perovskite SrTaO2N and the Ruddlesden–Popper Phase Sr2TaO3N

crystIT: Complexity and Configurational Entropy of Crystal Structures via Information Theory

Synergistic Influence of d0 (Nb5+) and d10 (Cd2+) Cations in Stabilizing Noncentrosymmetric Dion–Jacobson Layered Perovskites, A′Cd2Nb3O10 (A′ = Rb, Cs)

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Intergrowth between the Oxynitride Perovskite SrTaO₂N and the Ruddlesden–Popper Phase Sr₂TaO₃N

Intergrowth between the Oxynitride Perovskite SrTaO₂N and the Ruddlesden–Popper Phase Sr₂TaO₃N

Synergistic Influence of d⁰ (Nb⁵⁺) and d¹⁰ (Cd²⁺) Cations in Stabilizing Noncentrosymmetric Dion–Jacobson Layered Perovskites, A′Cd₂Nb₃O₁₀ (A′ = Rb, Cs)