Download or read book Growth and Structure of Complex Oxide Thin Films written by Vedran Vonk and published by . This book was released on 2006 with total page 159 pages. Available in PDF, EPUB and Kindle. Book excerpt:

Download or read book Metal Oxide Based Thin Film Structures written by Nini Pryds and published by Elsevier. This book was released on 2017-09-07 with total page 562 pages. Available in PDF, EPUB and Kindle. Book excerpt: Metal Oxide-Based Thin Film Structures: Formation, Characterization and Application of Interface-Based Phenomena bridges the gap between thin film deposition and device development by exploring the synthesis, properties and applications of thin film interfaces. Part I deals with theoretical and experimental aspects of epitaxial growth, the structure and morphology of oxide-metal interfaces deposited with different deposition techniques and new developments in growth methods. Part II concerns analysis techniques for the electrical, optical, magnetic and structural properties of thin film interfaces. In Part III, the emphasis is on ionic and electronic transport at the interfaces of Metal-oxide thin films. Part IV discusses methods for tailoring metal oxide thin film interfaces for specific applications, including microelectronics, communication, optical electronics, catalysis, and energy generation and conservation. This book is an essential resource for anyone seeking to further their knowledge of metal oxide thin films and interfaces, including scientists and engineers working on electronic devices and energy systems and those engaged in research into electronic materials. - Introduces the theoretical and experimental aspects of epitaxial growth for the benefit of readers new to the field - Explores state-of-the-art analysis techniques and their application to interface properties in order to give a fuller understanding of the relationship between macroscopic properties and atomic-scale manipulation - Discusses techniques for tailoring thin film interfaces for specific applications, including information, electronics and energy technologies, making this book essential reading for materials scientists and engineers alike

Download or read book Epitaxial Growth of Complex Metal Oxides written by Gertjan Koster and published by Woodhead Publishing. This book was released on 2022-04-22 with total page 534 pages. Available in PDF, EPUB and Kindle. Book excerpt: Epitaxial Growth of Complex Metal Oxides, Second Edition reviews techniques and recent developments in the fabrication quality of complex metal oxides, which are facilitating advances in electronic, magnetic and optical applications. Sections review the key techniques involved in the epitaxial growth of complex metal oxides and explore the effects of strain and stoichiometry on crystal structure and related properties in thin film oxides. Finally, the book concludes by discussing selected examples of important applications of complex metal oxide thin films, including optoelectronics, batteries, spintronics and neuromorphic applications. This new edition has been fully updated, with brand new chapters on topics such as atomic layer deposition, interfaces, STEM-EELs, and the epitaxial growth of multiferroics, ferroelectrics and nanocomposites. - Examines the techniques used in epitaxial thin film growth for complex oxides, including atomic layer deposition, sputtering techniques, molecular beam epitaxy, and chemical solution deposition techniques - Reviews materials design strategies and materials property analysis methods, including the impacts of defects, strain, interfaces and stoichiometry - Describes key applications of epitaxially grown metal oxides, including optoelectronics, batteries, spintronics and neuromorphic applications

Download or read book Strain induced Phenomenon in Complex Oxide Thin Films written by Ryan Haislmaier and published by . This book was released on 2016 with total page pages. Available in PDF, EPUB and Kindle. Book excerpt: 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.

Download or read book Thin Film Metal Oxides written by Shriram Ramanathan and published by Springer Science & Business Media. This book was released on 2009-12-03 with total page 344 pages. Available in PDF, EPUB and Kindle. Book excerpt: Thin Film Metal-Oxides provides a representative account of the fundamental structure-property relations in oxide thin films. Functional properties of thin film oxides are discussed in the context of applications in emerging electronics and renewable energy technologies. Readers will find a detailed description of deposition and characterization of metal oxide thin films, theoretical treatment of select properties and their functional performance in solid state devices, from leading researchers. Scientists and engineers involved with oxide semiconductors, electronic materials and alternative energy will find Thin Film Metal-Oxides a useful reference.

Download or read book Oxide Thin Films and Nanostructures written by Falko P. Netzer and published by Oxford University Press. This book was released on 2021-02-25 with total page 346 pages. Available in PDF, EPUB and Kindle. Book excerpt: Nanostructured oxide materials - ultra-thin films, nanoparticles and other nanometer-scale objects - play prominent roles in many aspects of our every-day life, in nature and in technological applications, among which is the all-oxide electronics of tomorrow. Due to their reduced dimensions and dimensionality, they strongly interact with their environment: gaseous atmosphere, water or support. Their novel physical and chemical properties are the subject of this book, from both a fundamental and an applied perspective. Oxide Thin Films and Nanostructures reviews and illustrates the various methodologies for their growth, fabrication, experimental and theoretical characterization. The role of key parameters such as film thickness, nanoparticle size and support interactions in driving their fundamental properties is underlined. At the ultimate thickness limit, two-dimensional oxide materials are generated, whose functionalities and potential applications are described. The emerging field of cation mixing is mentioned, which opens new avenues for engineering many oxide properties, as witnessed by natural oxide nanomaterials such as clay minerals, which, beyond their role at the Earth's surface, are now widely used in a whole range of human activities. Oxide nanomaterials are involved in many interdisciplinary fields of advanced nanotechnologies. Catalysis, photocatalysis, solar energy materials, fuel cells, corrosion protection, and biotechnological applications are amongst the areas where they are making an impact. The book outlines prototypical examples. A cautious glimpse into future developments of scientific activity is finally ventured to round off the presentation.

Download or read book A Study of Structure Induced Phase Phenomena in Perovskite Oxide Thin Films written by Jason Lapano and published by . This book was released on 2019 with total page pages. Available in PDF, EPUB and Kindle. Book excerpt: The three core tenants of materials science are theory, synthesis, and characterization. A solid theoretical framework is required for understanding of the problem at hand and using that knowledge to advance new areas of research. Synthesis of pristine materials is required to study the theory in a physical system and prevent misinterpretation of results. Complex structures and compositions are often the most interesting, and when defects and impurities are of interest, perfectly-imperfect samples are required which are often the most challenging to synthesize. Characterization of these materials is equally as important and complex, requiring careful sample preparation and experimental setups. Further, it is not always clear how to observe the property of scientific interest, and new characterization techniques must be developed. This dissertation focuses on using these three tenants to understand and advance the field of transition metal perovskite complex oxides using thin films of the incipient ferroelectrics CaTiO3 and SrTiO3 and antiferromagnetic Mott-Insulators LaVO3 and YVO3. The knowledge gained in this thesis can be applied to other complex oxide materials in better understanding magnetic and electronic transitions, high Tc superconductivity and quantum hall effect. Coupled with the relatively simple structure and ease of integration of multiple different chemical compounds into a single heterostructure leads to near numerous avenues to design functionality into materials.The first sections of this thesis begin with (1) an introduction to the basic science and past work in perovskite oxides, followed by (2) exploring the most common and promising synthesis routes, and finally (3) the various characterization methods used. The 4th chapter addresses the specific challenges of growth of ternary complex oxide thin films in an industrially profitable fashion. The three primary criterion that these deposition methods must adhere to is that they must (a) control film stoichiometry to less than 1% deviations, (b) deposit conformal coatings over standard 8 silicon wafers, (c) and exhibit deposition rates in excess of 1 m/hr. We show that these can be achieved using a hybrid molecular beam (hMBE) epitaxy approach and outline a route for commercially viable growth of complex oxides on silicon. This method is applied directly to the deposition of SrTiO3 on silicon for virtual single crystal perovskite substrates. The 5th chapter of this thesis discusses the effect of epitaxial strain, stoichiometry and interfacial coupling in heterostructures of complex oxides. In the (SrTiO3)n(CaTiO3)n series of superlattices grown by hMBE, it is found that interfacial energies play a large role in dictating the macroscopic properties, particularly ferroelectricity. In coherently strained thin films, both CaTiO3 and SrTiO3 exhibit relaxor-like ferroelectric behavior below room temperature. However, certain superlattices of these materials show nonpolar behavior when probed using second harmonic generation (SHG). High resolution scanning transmission electron microscopy (STEM) reveals that the symmetry in the superlattice is different from the individual parent compounds at the same strain state. It is found these are directly related to the high density of interfacial layers present in the films. Further, interfacial mixing of the constituent layers on certain superlattices leads to the development of a Ca1-xSrxTiO3 alloy which develops a ferroelectric moment at low temperatures, leading to spurious SHG signals. The findings of this experiment highlight the sensitivity of these complex layered structures to strain, stoichiometry, distortion coupling effects, and interfacial mixing.

Download or read book Atomic Scale Characterization of Complex Oxide Thin Films written by Meng Gu and published by . This book was released on 2011 with total page pages. Available in PDF, EPUB and Kindle. Book excerpt: Materials with the ABO3 perovskite structure possess a wide variety of properties including superconductivity, ferroelectric, and magnetic properties. These properties are highly tunable due to the fact that the B site cation can assume multiple valence states and its high structural stability allows for large scale doping and strain. Due to a reduced dimensionality, two dimensional thin films and superlattices grown using techniques such as pulsed laser deposition (PLD) often possess novel properties which differ from the bulk perovskite materials. The origins of these novel properties can be traced to interfacial chemical intermixing, electronic reconstruction, strain as well as defect formation, which cause significant changes in the electronic structures. Therefore, it is crucially important to investigate the atomic and electronic structures of the functional materials in order to understand the correlation between microstructures and physical properties. Chemically-sensitive Z-contrast imaging and bonding-sensitive electron energy loss spectroscopy (EELS) in aberration corrected scanning transmission electron microscopes (STEM) can directly characterize the local structure, strain, composition and bonding on the atomic scale. Determination of the atomic and electronic structures of the interfaces and defects in the thin films can then be correlated with the magnetic and transport properties. Therefore, the understanding of the structure-property relationship for several different systems of perovskite oxide thin films and superlattices were developed on the atomic scale. Multifunctional superlattices composed of ferromagnetic (FM) La(0.7)Sr(0.3)MnO3 (LSMO) and antiferromagnetic (AFM) La(0.7)Sr(0.3)FeO3 (LSFO) have potential applications for next generation data storage and logic devices. Defect formation, driven by strain relaxation in the LSMO/LSFO superlattices can modify not only the structure and surface sharpness, but also the functional properties of the superlattice. Stacking faults were found as one efficient way of strain relaxation while maintaining robust antiferromagnetic properties for a thin [3LSMO][6LSFO] superlattice (repeating motif composed of 3 unit-cell LSMO sublayer and 6 unit-cell LSFO sublayer). On the other hand, for a fully strained [3LSMO][6LSFO], large inter-diffusion across the interface between the LSMO and LSFO layers was detected in EELS line scans, resulting in deteriorated AFM properties. When a [6LSMO][6LSFO] superlattice with one micron thickness, a high density of nanoflowers and cracks/pinholes were observed to result from strain relaxation. The formation of these nanoflowers and cracks/pinholes was suppressed by increasing the growth rate and thereby reducing the growth time and overall thermal treatment of the sample. Strain relaxation was shown to be directly related to the growth conditions and have a large effect on both the structure and functional properties of the superlattices. A series of superlattices composed of non-magnetic La(0.5)Sr(0.5)TiO3 (LSTO) and ferromagnetic LSMO were grown on single crystal oxide substrates with different amounts of misfit strain. No significant electronic structure changes along the interfaces was observed in this series of superlattices as revealed by atomic resolution EELS. In comparison, charge transfer effect was reported for the LSMO/STO superlattices and was shown to cause an ultrathin magnetic dead layer along the interfaces. Thus, compared with the LSMO/STO superlattice, composition tuning of the sublayers was proven to be efficient in controlling the interfacial charge transfer effects in a superlattice. In addition, tetragonal distortion was found to reduce the ferromagnetic ordering, decrease the Tc, increase the resistivity, and even lead to metal-insulator transitions of the superlattices. The strain relaxation defects such as dislocations and low angle grain boundaries serve as important pinning sites for magnetic domains, leading to enhanced coercive field strength. In order to determine the properties of an intermixed interface layer, we have performed a detailed study of the solid solution between LSMO and LSFO, i.e. La(0.7)Sr(0.3)Mn(0.5)Fe(0.5)O3 (LSMFO). A large target-substrate distance during the PLD growth led to cation segregation in the LSMFO film. Cation segregation could cause the formation of diverse local magnetic ordering and B site valence states due to the different local stoichiometry and coordination environment. For the cation segregated LSFMO films, robust ferromagnetic and antiferromagnetic coupling was observed at 150K and room temperature. Decreasing the target-substrate distance resulted to a homogeneous cation distribution in the film, without any ferromagnetic ordering as expected. This result suggests the important role of target-substrate distance and the kinetic energy of the plume species on the crystalline quality and functional properties of perovskite oxide thin films. La(x)Sr(1-x)TiO3 possesses a wide range of functional properties which make it an attractive candidate material for applications such as the conductive buffer for high temperature superconductor growth, transparent conductors, and anodes in solid oxide fuel cells. La(0.5)Sr(0.5)TiO3 thin films were grown using PLD and the resistivity was found to be highly dependent on the O2 background pressure used in the deposition. However, a thin film which was deposited as a single phase film was transformed into a semi-ordered superlattice with TiO2 rich stacking faults and distorted lattices upon exposure to high oxygen pressure (~200torr) during the cooling procedure after deposition. This phase change stabilized Ti4+ ions and dramatically increased the resistivity of the film. In addition, a two dimensional free electron gas could be constructed by confining a few unit cells of La doped STO with STO spacer layers. Our study showed that charge transfer over a distance of ~2 u.c. was present in Sr(0.75)La(0.25)TiO3/STO superlattices. This thickness defined the lower limit for the thickness of the STO spacers in order to confine the charge carriers into two dimensions; secondly, the La dopants were shown to be less localized in thicker superlattice (~100nm) due to interdiffusion upon extended thermal exposure. This information provided important feedback on the fabrication and utilization of this material.In conclusion, several perovskite thin film systems with fascinating properties have been explored in this thesis. Strain states and strain relaxations, defect formation, interfacial atomic mixing, charge transfer, and cation segregation were shown to have profound effect on the functional properties of complex oxide thin film systems. Atomic resolution Z-contrast imaging and EELS provide extremely useful information on the structural and electronic structure variations, which enable us to see the whole picture of growth, structure and properties' interactions.

Download or read book Epitaxial and Lateral Solid phase Crystallization of Complex Oxides written by Yajin Chen and published by . This book was released on 2019 with total page 150 pages. Available in PDF, EPUB and Kindle. Book excerpt: The crystallization of complex-oxide materials through a transformation from the amorphous to crystalline forms presents a range of new opportunities to synthesize new materials, and simultaneously poses important scientific challenges. New crystallization method complements more conventional vapor-phase epitaxy techniques for epitaxial complex-oxide thin film growth that involve long-range surface diffusion on 2D planar crystal surfaces. The vapor-phase techniques are not readily adaptable to creating nanoscale epitaxial complex-oxide crystals. The alternative synthesis method described in this thesis is solid-phase crystallization, which is the crystallization of amorphous oxides, often in the form of thin films, by post-deposition heating. The creation of epitaxial complex-oxide nanostructures can facilitate their integration in 3D electronic, optoelectronic and ionic devices. Epitaxial complex-oxide crystals in intricate geometries can be created by solid-phase crystallization employing patterned substrates with a distribution of isolated crystalline seeds. This method requires the study of distinct crystal growth and nucleation kinetics on epitaxial and non-epitaxial surfaces. Nanoscale seeded crystallization can be achieved by understanding the relative rates of nucleation and lateral crystal growth processes, and the role of seeds in determining the overall orientation of the resulting crystals. Epitaxial complex-oxide thin films in intricate geometries with an expanded range of compositions can be created by combining the use of atomic layer deposition (ALD) and solid-phase crystallization, with the development of new ALD procedures to deposit amorphous oxide films and the study of the subsequent crystallization processes to select the crystalline structures of the crystallized film. ALD itself allows for the conformal deposition of thin films over non-planar surfaces. Solid-phase crystallization can also be used to deposit epitaxial complex-oxide thin films with a wider range of compositions, including those that cannot be deposited from the vapor phase at high temperatures. Such oxides include the oxides that have complex compositions and volatile components. The different kinetic constraints of solid-phase crystallization allow the epitaxial growth of those oxide thin films because of the slow diffusion in the solid state at relatively low crystallization temperatures. This thesis describes the discovery that, at low crystallization temperatures, epitaxial crystal growth of the model perovskite SrTiO3 on single-crystal SrTiO3 propagates over long distances without nucleation of SrTiO3 on Si with a native oxide. Two kinds of isolated nanoscale seed crystals are employed to study the seeded lateral crystallization of SrTiO3, yielding highly similar results. Micron-scale crystalline regions form surrounding the seeds before encountering separately nucleated crystals away from the seeds. Seed crystals play an important role in determining the orientations of the resulting crystals. New chemical precursors and ALD procedures were developed to grow amorphous PrAlO3 films. An epitaxial [lowercase gamma]-Al2O3 layer formed at the interface between the PrAlO3 film and (001) SrTiO3 substrate during the deposition. Epitaxial PrAlO3 films were achieved on (001) [lowercase gamma]-Al2O3/SrTiO3 by solid-phase epitaxy. The study of SrTiO3 and PrAlO[3] is also applicable to a series of chemically and structurally similar functional ABO3 compounds. The concepts of solid-phase crystallization also apply to oxides with multiple metal ions and more complex crystal structure. The kinetic processes occurring during the crystallization of ScAlMgO4, on (0001) sapphire substrates are quite different at two different temperatures. Epitaxial ScAlMgO4 crystals grow through the film thickness at a crystallization temperature of 950 °C. Solid-state reaction and evaporation of the component Sc prohibits the formation of large ScAlMgO4 crystals at a crystallization temperature of 1400 °C. Low-temperature crystallization can be used to create epitaxial oxide thin films with complex compositions and volatile components.

Download or read book Perovskite Oxide Thin Film Growth Characterization and Stability written by Andrew Izumi and published by . This book was released on 2015 with total page pages. Available in PDF, EPUB and Kindle. Book excerpt: Studies into a class of materials known as complex oxides have evoked a great deal of interest due to their unique magnetic, ferroelectric, and superconducting properties. In particular, materials with the ABO3 perovskite structure have highly tunable properties because of the high stability of the structure, which allows for large scale doping and strain. This also allows for a large selection of A and B cations and valences, which can further modify the material's electronic structure. Additionally, deposition of these materials as thin films and superlattices through techniques such as pulsed laser deposition (PLD) results in novel properties due to the reduced dimensionality of the material. The novel properties of perovskite oxide heterostructures can be traced to a several sources, including chemical intermixing, strain and defect formation, and electronic reconstruction. The correlations between microstructure and physical properties must be investigated by examining the physical and electronic structure of perovskites in order to understand this class of materials. Some perovskites can undergo phase changes due to temperature, electrical fields, and magnetic fields. In this work we investigated Nd0.5Sr0.5MnO3 (NSMO), which undergoes a first order magnetic and electronic transition at T=158K in bulk form. Above this temperature NSMO is a ferromagnetic metal, but transitions into an antiferromagnetic insulator as the temperature is decreased. This rapid transition has interesting potential in memory devices. However, when NSMO is deposited on (001)-oriented SrTiO3 (STO) or (001)-oriented (LaAlO3)0.3-(Sr2AlTaO6)0.7 (LSAT) substrates, this transition is lost. It has has been reported in the literature that depositing NSMO on (110)-oriented STO allows for the transition to reemerge due to the partial epitaxial growth, where the NSMO film is strained along the [001] surface axis and partially relaxed along the [11̄0] surface axis. This allows the NSMO film enough freedom of movement to undergo a shear strain along the [11̄0] axes, allowing the NSMO film to switch phases. It was found that the desired magnetic and electrical properties were closely tied to the structural properties, which were highly sensitive to the precise growth conditions. These perovskite oxides can be further geometrically constrained by patterning, resulting in additional novel magnetic and electrical properties. One such method of patterning involves implanting Ar into a film to locally destabilize the ordered perovskite structure, therefore suppress the magnetic and electrical properties. However, to fully integrate this technique into devices which require multi-planar processes, the ability for a patterned perovskite film to withstand high temperature anneals is crucial in creating more advanced structures. The stability of Ar-implanted La0.7Sr0.3MnO3 (LSMO) thin films was studied upon annealing at 400°C, 500°C, and 600°C. The LSMO retained its amorphous structure with little ferromagnetism after a 400°C anneal, but anneals at 500°C and 600°C resulted in partial recrystallization and a return of the ferromagnetic properties. This recrystallized film displayed semiconducting properties with a lower Curie temperature than the as deposited film. The deposition of an La0.7Sr0.3FeO3 (LSFO) film onto an Ar implanted LSMO film at 400°C caused the LSMO film to almost fully recrystallize, suggesting that the deposition process also recrystallizes the Ar-implanted film. In conclusion, two perovskites films were explored in this thesis. NSMO films proved to be very sensitive to growth conditions, and Ar-implanted LSMO films quickly recrystallized past 400°C or a subsequent film deposition. These studies provide useful information on the structural and electronic transformations these films go through during heat treatment and strain engineering.

Download or read book In Situ Real Time Studies of Complex Oxide Thin Film Growth written by Alexander Heinrich Mueller and published by . This book was released on 2002 with total page 258 pages. Available in PDF, EPUB and Kindle. Book excerpt:

Download or read book Spectroscopy of Complex Oxide Interfaces written by Claudia Cancellieri and published by Springer. This book was released on 2018-04-09 with total page 326 pages. Available in PDF, EPUB and Kindle. Book excerpt: This book summarizes the most recent and compelling experimental results for complex oxide interfaces. The results of this book were obtained with the cutting-edge photoemission technique at highest energy resolution. Due to their fascinating properties for new-generation electronic devices and the challenge of investigating buried regions, the book chiefly focuses on complex oxide interfaces. The crucial feature of exploring buried interfaces is the use of soft X-ray angle-resolved photoemission spectroscopy (ARPES) operating on the energy range of a few hundred eV to increase the photoelectron mean free path, enabling the photons to penetrate through the top layers – in contrast to conventional ultraviolet (UV)-ARPES techniques. The results presented here, achieved by different research groups around the world, are summarized in a clearly structured way and discussed in comparison with other photoemission spectroscopy techniques and other oxide materials. They are complemented and supported by the most recent theoretical calculations as well as results of complementary experimental techniques including electron transport and inelastic resonant X-ray scattering.

Download or read book Chemical Solution Deposition of Functional Oxide Thin Films written by Theodor Schneller and published by Springer Science & Business Media. This book was released on 2014-01-24 with total page 801 pages. Available in PDF, EPUB and Kindle. Book excerpt: This is the first text to cover all aspects of solution processed functional oxide thin-films. Chemical Solution Deposition (CSD) comprises all solution based thin- film deposition techniques, which involve chemical reactions of precursors during the formation of the oxide films, i. e. sol-gel type routes, metallo-organic decomposition routes, hybrid routes, etc. While the development of sol-gel type processes for optical coatings on glass by silicon dioxide and titanium dioxide dates from the mid-20th century, the first CSD derived electronic oxide thin films, such as lead zirconate titanate, were prepared in the 1980’s. Since then CSD has emerged as a highly flexible and cost-effective technique for the fabrication of a very wide variety of functional oxide thin films. Application areas include, for example, integrated dielectric capacitors, ferroelectric random access memories, pyroelectric infrared detectors, piezoelectric micro-electromechanical systems, antireflective coatings, optical filters, conducting-, transparent conducting-, and superconducting layers, luminescent coatings, gas sensors, thin film solid-oxide fuel cells, and photoelectrocatalytic solar cells. In the appendix detailed “cooking recipes” for selected material systems are offered.

Download or read book Advanced Nano Deposition Methods written by Yuan Lin and published by John Wiley & Sons. This book was released on 2016-08-29 with total page 328 pages. Available in PDF, EPUB and Kindle. Book excerpt: This concise reference summarizes the latest results in nano-structured thin films, the first to discuss both deposition methods and electronic applications in detail. Following an introduction to this rapidly developing field, the authors present a variety of organic and inorganic materials along with new deposition techniques, and conclude with an overview of applications and considerations for their technology deployment.

Download or read book Functional Complex Oxide Thin Films and Related Superlattices Grown Via Pulsed Laser Deposition written by Joseph A. Cianfrone and published by . This book was released on 2011 with total page pages. Available in PDF, EPUB and Kindle. Book excerpt: ABSTRACT: Oxide electronics offer a wide array of interesting properties, including ferromagnetism, ferroelectricity and superconductivity. This dissertation investigates the transport, magnetic, and structural properties of several perovskite and spinel material systems, with particular interest in their manipulation at the nanoscale through the growth of functional heterostructures. Spinel phase ZnCo2O4 is investigated as a ferromagnetic semiconductor whose carrier type changes with oxygen concentration. The perovskite system of K(Ta, Nb)O3 is investigated for its interesting properties as a solid solution which exhibits a ferroelectric transition dependent on composition. Its thin film epitaxial growth modes are investigated via reflection high energy electron diffraction, with particular attention paid to the volatile potassium ion. Superlattices of K(Ta, Nb)O3 and SrTiO3 are also investigated for the possibility of dielectric enhancement and conductive interfaces. The multiferroic properties of BaFeO3 K(Ta, Nb)O3 superlattices are investigated, with particular attention paid to the role of magnetoelectric coupling and strain as stabilizing mechanisms.

Download or read book Thin Films and Heterostructures for Oxide Electronics written by Satishchandra B. Ogale and published by Springer Science & Business Media. This book was released on 2005-11-21 with total page 416 pages. Available in PDF, EPUB and Kindle. Book excerpt: Oxides form a broad subject area of research and technology development which encompasses different disciplines such as materials science, solid state chemistry, physics etc. The aim of this book is to demonstrate the interplay of these fields and to provide an introduction to the techniques and methodologies involving film growth, characterization and device processing. The literature in this field is thus fairly scattered in different research journals covering one or the other aspect of the specific activity. This situation calls for a book that will consolidate this information and thus enable a beginner as well as an expert to get an overall perspective of the field, its foundations, and its projected progress.

Download or read book Multifunctional Oxide Heterostructures written by Evgeny Y. Tsymbal and published by Oxford University Press. This book was released on 2012-08-30 with total page 429 pages. Available in PDF, EPUB and Kindle. Book excerpt: This volume explores the rapidly developing field of oxide thin-films and heterostructures, which exhibit unusual physical properties interesting from the fundamental point of view and for device application. The chapters discuss topics that represent some of the key innovations in the field over recent years.