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Author: Kyu Ho Lee
Publisher:
ISBN:
Category :
Languages : en
Pages :
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The discovery of novel materials brings diverse scientific opportunities by introducing novel physical phenomena, opening ways to verify and formulate theories, and enabling revolutionary industrial applications. Stabilization of novel structures in complex oxide materials is in particular of strong interest, as these materials display a broad spectrum of physical and chemical properties, along with dramatic variations in the material properties upon subtle changes in their structures. The stabilization of a material is largely governed by thermodynamic variables such as temperature, pressure, and chemical potential. Hence, stabilizing a novel, unconventional material usually requires that one or more of these thermodynamic variables are maintained at values far from the standard conditions. Epitaxial thin film growth, in which the target material is artificially exposed to large effective pressure due to the forced geometrical match with an underlying substrate with different unit cell dimensions, is a well-established example that satisfies this criterion. Another relevant example is ion intercalation, where relatively small ions such as lithium are inserted into a material (usually a two-dimensional van der Waals material) by electrochemically tuning the chemical potential of the ions, thereby changing the material's physical and chemical properties. In this work, I will show that controlled ionic modification via deintercalation can be an effective approach to stabilize novel complex oxides and demonstrate this in two material systems. First, I will discuss the meta-stable formation of IrO$_{x}$ via deintercalation of strontium in SrIrO$_{3}$, which demonstrates high oxygen evolution reaction (OER) activity and good chemical stability in acid. This motivates design strategies for high-activity OER catalysts such as the stabilization of a novel columbite polymorph of IrO$_{2}$, which I demonstrate can be achieved via epitaxial thin film growth. Second, I will show that oxygen deintercalation of perovskite nickelate stabilizes infinite-layer \textit{Ln}NiO$_{2}$ (\textit{Ln} = lanthanide), which upon hole-doping hosts unconventional superconductivity and shows striking similarities in the superconducting phase diagram to that of the cuprates despite marked differences in the two systems. Overall, this work highlights deintercalation as a powerful technique to stabilize novel complex oxides that is widely applicable to various material systems. As this approach has been rather underutilized relative to other conventional methods, there is great potential to further discover novel materials using this technique.
Author: Kyu Ho Lee
Publisher:
ISBN:
Category :
Languages : en
Pages :
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Book Description
The discovery of novel materials brings diverse scientific opportunities by introducing novel physical phenomena, opening ways to verify and formulate theories, and enabling revolutionary industrial applications. Stabilization of novel structures in complex oxide materials is in particular of strong interest, as these materials display a broad spectrum of physical and chemical properties, along with dramatic variations in the material properties upon subtle changes in their structures. The stabilization of a material is largely governed by thermodynamic variables such as temperature, pressure, and chemical potential. Hence, stabilizing a novel, unconventional material usually requires that one or more of these thermodynamic variables are maintained at values far from the standard conditions. Epitaxial thin film growth, in which the target material is artificially exposed to large effective pressure due to the forced geometrical match with an underlying substrate with different unit cell dimensions, is a well-established example that satisfies this criterion. Another relevant example is ion intercalation, where relatively small ions such as lithium are inserted into a material (usually a two-dimensional van der Waals material) by electrochemically tuning the chemical potential of the ions, thereby changing the material's physical and chemical properties. In this work, I will show that controlled ionic modification via deintercalation can be an effective approach to stabilize novel complex oxides and demonstrate this in two material systems. First, I will discuss the meta-stable formation of IrO$_{x}$ via deintercalation of strontium in SrIrO$_{3}$, which demonstrates high oxygen evolution reaction (OER) activity and good chemical stability in acid. This motivates design strategies for high-activity OER catalysts such as the stabilization of a novel columbite polymorph of IrO$_{2}$, which I demonstrate can be achieved via epitaxial thin film growth. Second, I will show that oxygen deintercalation of perovskite nickelate stabilizes infinite-layer \textit{Ln}NiO$_{2}$ (\textit{Ln} = lanthanide), which upon hole-doping hosts unconventional superconductivity and shows striking similarities in the superconducting phase diagram to that of the cuprates despite marked differences in the two systems. Overall, this work highlights deintercalation as a powerful technique to stabilize novel complex oxides that is widely applicable to various material systems. As this approach has been rather underutilized relative to other conventional methods, there is great potential to further discover novel materials using this technique.
Author: Shaun R. Bruno
Publisher:
ISBN: 9781303806292
Category : Cathodes
Languages : en
Pages : 233
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Author: Thomas Vogt
Publisher: World Scientific Publishing Company
ISBN: 9789813278578
Category : Science
Languages : en
Pages : 0
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This book provides a unique look at the chemistry and properties of complex metal oxides from the perspectives of some of the most active researchers on this class of materials. Applications of complex oxide materials are highly varied. Topics reviewed in this volume include solid-state battery research, the chemistry of transparent conductors, ternary uranium oxides, magnetic perovskites, non-linear optical materials, complex molybdenum-vanadium bronzes and other complex materials used in selective oxidation catalysis. It is written to serve as an introduction to the subject for and those beginning to work on these materials, particularly new graduate students.
Author: Jan Seidel
Publisher: Walter de Gruyter
ISBN: 9783110304244
Category : Science
Languages : en
Pages : 300
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Book Description
Complex oxides have a wide variety of modern applications nanoelectronics, thermoelectronics, photo- and electrochemistry, as battery materials, catalysts and for energy conversion and storage. In a clear and accessible waythe text provides an overview of all important materials classes, such as superconductors, manganites, (multi-) ferroics, discusses nanoscale and interface properties and important synthesis and characterization methods.
Author: Altynbek Murat
Publisher:
ISBN:
Category : Electric conductivity
Languages : en
Pages : 0
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"Ab-initio density functional approach is employed to investigate the structural, optical, and electronic properties of twelve undoped (non)stoichiometric multicomponent oxides with layered structure RAMO4 [R3 =In or Sc, A3 =Al or Ga, and M2 - Ca, Cd, Mg, or Zn], as candidates for novel transparent conducting oxides. The compositional complexity of RAMO4 leads to a wide range of band gaps varying from 2.45eV for InGaCdO4 to 6.29 eV for ScAlMgO4. We find that despite the different band gaps in the constituent binary oxides, namely, 2-4 eV in CdO, In2O3, or AnO; 5-6 eV for Ga2O3 or Sc2O3; and 7-9 eV in CaO, MgO, or Al2O3, the states of all cations contribute to the bottom of the conduction band of RAMO4. We show that this hybrid nature of the conduction band originates from the unusual fivefold atomic coordination of A3+ and M2+ cations and suggests that both structurally and chemically distinct layers of RAMO4 are expected to participate in carrier transport. This is consistent with the obtained isotropic electron effective mass of 0.3-0.5 m[subscript e]. Next, in order to understand the carrier generation mechanism in RAMO4, we have systematically investigated the formation of native point defects in three representative InAMO4 oxides. We find that the donor antisite defect in InGaZnO4 and InAlZnO4 occur in higher concentrations than oxygen vacancies which are major donors in binary oxides. Also in contrast to the binary TCOs, the formation energy of cation vacancies is significantly lower in InAMO4 owing to a large structural relaxation around the defect. As a result, the equilibrium Fermi level is pushed away from the conduction band and deeper into the band gap. The results agree well with the observed dependence of the conductivity on the oxygen partial pressure in InGaZnO4. These systematic investigations provide a significant insight into the role of chemical composition and structural complexity of RAMO4 materials on the carrier generation mechanisms and the resulting properties"--Abstract, leaf iv
Author: J. M. S. Skakle
Publisher:
ISBN:
Category :
Languages : en
Pages :
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Author:
Publisher: Newnes
ISBN: 0080965296
Category : Science
Languages : en
Pages : 7694
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Book Description
Comprehensive Inorganic Chemistry II, Nine Volume Set reviews and examines topics of relevance to today’s inorganic chemists. Covering more interdisciplinary and high impact areas, Comprehensive Inorganic Chemistry II includes biological inorganic chemistry, solid state chemistry, materials chemistry, and nanoscience. The work is designed to follow on, with a different viewpoint and format, from our 1973 work, Comprehensive Inorganic Chemistry, edited by Bailar, Emeléus, Nyholm, and Trotman-Dickenson, which has received over 2,000 citations. The new work will also complement other recent Elsevier works in this area, Comprehensive Coordination Chemistry and Comprehensive Organometallic Chemistry, to form a trio of works covering the whole of modern inorganic chemistry. Chapters are designed to provide a valuable, long-standing scientific resource for both advanced students new to an area and researchers who need further background or answers to a particular problem on the elements, their compounds, or applications. Chapters are written by teams of leading experts, under the guidance of the Volume Editors and the Editors-in-Chief. The articles are written at a level that allows undergraduate students to understand the material, while providing active researchers with a ready reference resource for information in the field. The chapters will not provide basic data on the elements, which is available from many sources (and the original work), but instead concentrate on applications of the elements and their compounds. Provides a comprehensive review which serves to put many advances in perspective and allows the reader to make connections to related fields, such as: biological inorganic chemistry, materials chemistry, solid state chemistry and nanoscience Inorganic chemistry is rapidly developing, which brings about the need for a reference resource such as this that summarise recent developments and simultaneously provide background information Forms the new definitive source for researchers interested in elements and their applications; completely replacing the highly cited first edition, which published in 1973
Author: Ryan Haislmaier
Publisher:
ISBN:
Category :
Languages : en
Pages :
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Complex oxide materials wield an immense spectrum of functional properties such as ferroelectricity, ferromagnetism, magnetoelectricity, optoelectricity, optomechanical, magnetoresistance, superconductivity, etc. The rich coupling between charge, spin, strain, and orbital degrees of freedom makes this material class extremely desirable and relevant for next generation electronic devices and technologies which are trending towards nanoscale dimensions. Development of complex oxide thin film materials is essential for realizing their integration into nanoscale electronic devices, where theoretically predicted multifunctional capabilities of oxides could add tremendous value. Employing thin film growth strategies such as epitaxial strain and heterostructure interface engineering can greatly enhance and even unlock novel material properties in complex oxides, which will be the main focus of this work. However, physically incorporating oxide materials into devices remains a challenge. While advancements in molecular beam epitaxy (MBE) of thin film oxide materials has led to the ability to grow oxide materials with atomic layer precision, there are still major limitations such as controlling stoichiometric compositions during growth as well as creating abrupt interfaces in multi-component layered oxide structures. The work done in this thesis addresses ways to overcome these limitations in order to harness intrinsic material phenomena.The development of adsorption-controlled stoichiometric growth windows of CaTiO3 and SrTiO3 thin film materials grown by hybrid MBE where Ti is supplied using metal-organic titatnium tetraisopropoxide material is thoroughly outlined. These growth windows enable superior epitaxial strain-induced ferroelectric and dielectric properties to be accessed as demonstrated by chemical, structural, electrical, and optical characterization techniques. For tensile strained CaTiO3 and compressive strained SrTiO3 films, the critical effects of nonstoichiometry on ferroelectric properties are investigated, where enhanced ferroelectric responses are only found for stoichiometric films grown inside of the growth windows, whereas outside of the optimal growth window conditions, ferroelectric properties are greatly deteriorated and eventually disappear for highly nonstoichiometric film compositions. Utilizing these stoichiometric growth windows, high temperature polar phase transitions are discovered for compressively strained CaTiO3 films with transition temperatures in excess of 700 K, rendering this material as a strong candidate for high temperature electronic applications. Beyond the synthesis of single phase materials using hybrid MBE, a methodology is presented for constructing layered (SrTiO3)n/(CaTiO3)n superlattice structures, where precise control over the unit cell layering thickness (n) is demonstrated using in-situ reflection high energy electron diffraction. The effects of interface roughness and layering periodicity (n) on the strain-induced ferroelectric properties for a series of n=1-10 (SrTiO3)n/(CaTiO3)n superlattice films are investigated. It is found that the stabilization of a ferroelectric phase is independent of n, but is however strongly dominated by the degree of interface roughness which is quantified by measuring the highest nth order X-ray diffraction peak splitting of each superlattice film. A counter-intuitive realization is made whereby a critical amount of interface roughness is required in order to enable the formation of the predicted strain-stabilized ferroelectric phase, whereas sharp interfaces actually suppress this ferroelectric phase from manifesting. It is shown how high-quality complex oxide superlattices can be constructed using hybrid MBE technique, allowing the ability to control layered materials at the atomic scale. Furthermore, a detailed growth methodology is provided for constructing a layered n=4 SrO(SrTiO3)n Ruddlesden-Popper (RP) phase by hybrid MBE, where the ability to deposit single monolayers of SrO and TiO2 is utilized to build the RP film structure over a time period of 5 hours. This is the first time that a thin film RP phase has been grown using hybrid MBE, where an a stable control over the fluxes is demonstrated during relatively long time periods of growth, which advantageously facilitates the synthesis of high-quality RP materials with excellent structural and chemical homogeneity.Additionally, this work demonstrates some major advancements in optical second harmonic generation (SHG) characterization techniques of ferroelectric thin film materials. The SHG characterization techniques developed here proved to be the bread-and-butter for most of the work performed in this thesis, providing a powerful tool for identifying the existence of strain-induced ferroelectric phases, including their temperature dependence and polar symmetry. The work presented in this dissertation will hopefully provide a preliminary road map for future hybrid MBE growers, scientists and researchers, to develop and investigate epitaxial strain and heterostructure layering induced phenomena in other complex oxide systems.
Author: Douglas J. Buttrey
Publisher:
ISBN: 9789813278585
Category : SCIENCE
Languages : en
Pages : 238
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Author: James Paul Thiel
Publisher:
ISBN:
Category :
Languages : en
Pages :
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