Phonons in complex oxides PDF Download
Are you looking for read ebook online? Search for your book and save it on your Kindle device, PC, phones or tablets. Download Phonons in complex oxides PDF full book. Access full book title Phonons in complex oxides by Neno Todorov. Download full books in PDF and EPUB format.
Author: Neno Todorov
Publisher:
ISBN:
Category :
Languages : en
Pages : 85
Get Book Here
Book Description
Dans cette thèse, une étude vibrationnelle de plusieurs oxydes complexes a été effectuée sur différentes structures de type perovskites : les matériaux orthorhombiques YCrO3 et YMnO3 rhomboédrique Sc3CrO6 et de type C Sc2O3 . La principale méthode utilisée pour la caractérisation des échantillons est la spectroscopie de diffusion Raman. La composition chimique et la structure cristalline des oxydes a été déterminée par diffraction des rayons X sur poudres et cristaux et par microscopie électronique à balayage. Des calculs de dynamique de réseau ont été menés à bien pour déterminer l'origine des bandes spectrales Raman observées, en utilisant des modèles à coquilles ou des méthodes ab initio. Une analyse systématique des données structurales et de diffusion Raman a porté sur les cristaux du type R3+B3+O3 (R- terre rare, B=Al,Sc,Ti, V,Cr,Mn,Fe,Co,Ni, et Ga) pour établir la relation entre la fréquence de modes Raman mous et le ou les angle (s) d'inclinaison des octaèdres BO6. Une dépendance générale entre les fréquences Raman et le paramètre cristallin a été établie pour les sesquioxydes cubiques de terres rares R2O3.
Author: Neno Todorov
Publisher:
ISBN:
Category :
Languages : en
Pages : 85
Get Book Here
Book Description
Dans cette thèse, une étude vibrationnelle de plusieurs oxydes complexes a été effectuée sur différentes structures de type perovskites : les matériaux orthorhombiques YCrO3 et YMnO3 rhomboédrique Sc3CrO6 et de type C Sc2O3 . La principale méthode utilisée pour la caractérisation des échantillons est la spectroscopie de diffusion Raman. La composition chimique et la structure cristalline des oxydes a été déterminée par diffraction des rayons X sur poudres et cristaux et par microscopie électronique à balayage. Des calculs de dynamique de réseau ont été menés à bien pour déterminer l'origine des bandes spectrales Raman observées, en utilisant des modèles à coquilles ou des méthodes ab initio. Une analyse systématique des données structurales et de diffusion Raman a porté sur les cristaux du type R3+B3+O3 (R- terre rare, B=Al,Sc,Ti, V,Cr,Mn,Fe,Co,Ni, et Ga) pour établir la relation entre la fréquence de modes Raman mous et le ou les angle (s) d'inclinaison des octaèdres BO6. Une dépendance générale entre les fréquences Raman et le paramètre cristallin a été établie pour les sesquioxydes cubiques de terres rares R2O3.
Author: Fryderyk Lyzwa
Publisher:
ISBN: 9788303111869
Category : Complex compounds
Languages : en
Pages : 0
Get Book Here
Book Description
This PhD thesis reports on investigations of several oxide-based materials using advanced infrared and Raman spectroscopy techniques and in combination with external stimuli such as high magnetic or electric field, sptial confinement in thin film heterostructures and the radiation with UV light. This leads to new results in the fields of superconductivity, electronic polarization states and nanoscale phenomena. Among these, the observation of anomalous polar moments is of great relevance for understanding the electric-field-induced metal-to-insulator transistion; and the demonstration that confocal Raman spectroscopy of backfolded acoustic photons in metal-oxide multilayers can be used as a powerful characterization tool for monitoring their interface properties and layer thickness is an important technical development for the engineering of such functional oxide heterostructures.
Author: 楊濟源
Publisher:
ISBN:
Category :
Languages : en
Pages :
Get Book Here
Book Description
Author: Fryderyk Lyzwa
Publisher: Springer Nature
ISBN: 3031118669
Category : Technology & Engineering
Languages : en
Pages : 158
Get Book Here
Book Description
This PhD thesis reports on investigations of several oxide-based materials using advanced infrared and Raman spectroscopy techniques and in combination with external stimuli such as high magnetic or electric field, sptial confinement in thin film heterostructures and the radiation with UV light. This leads to new results in the fields of superconductivity, electronic polarization states and nanoscale phenomena. Among these, the observation of anomalous polar moments is of great relevance for understanding the electric-field-induced metal-to-insulator transistion; and the demonstration that confocal Raman spectroscopy of backfolded acoustic photons in metal-oxide multilayers can be used as a powerful characterization tool for monitoring their interface properties and layer thickness is an important technical development for the engineering of such functional oxide heterostructures.
Author: Claudia Cancellieri
Publisher: Springer
ISBN: 3319749897
Category : Technology & Engineering
Languages : en
Pages : 326
Get Book Here
Book Description
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.
Author: Gertjan Koster
Publisher: Elsevier
ISBN: 1782422552
Category : Technology & Engineering
Languages : en
Pages : 505
Get Book Here
Book Description
The atomic arrangement and subsequent properties of a material are determined by the type and conditions of growth leading to epitaxy, making control of these conditions key to the fabrication of higher quality materials. Epitaxial Growth of Complex Metal Oxides reviews the techniques involved in such processes and highlights recent developments in fabrication quality which are facilitating advances in applications for electronic, magnetic and optical purposes. Part One reviews the key techniques involved in the epitaxial growth of complex metal oxides, including growth studies using reflection high-energy electron diffraction, pulsed laser deposition, hybrid molecular beam epitaxy, sputtering processes and chemical solution deposition techniques for the growth of oxide thin films. Part Two goes on to 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 in Part Three. Provides valuable information on the improvements in epitaxial growth processes that have resulted in higher quality films of complex metal oxides and further advances in applications for electronic and optical purposes Examines the techniques used in epitaxial thin film growth Describes the epitaxial growth and functional properties of complex metal oxides and explores the effects of strain and defects
Author: A R Bishop
Publisher: World Scientific
ISBN: 981448671X
Category : Science
Languages : en
Pages : 233
Get Book Here
Book Description
There is considerable interest in the intrinsically multiscale structure and dynamics of complex electronic oxides, especially since these materials include those of technological importance, such as colossal magnetoresistance manganites and cuprate high temperature superconductors. Current microscopies, such as diffuse X-ray and inelastic neutron scattering, electromagnetic and acoustic response, NMR and scanning tunneling microscope probes, have revealed static and dynamic multiscale patterns in charge positioning, lattice structure and magnetic orientation, that respond to both external stress and magnetic field. These self-organized patterns include charge and orbital ordering; stripes in strain/spin; and labyrinth-like conductance modulations. The materials exhibit nanoscale phase segregation and mesoscale inhomogeneous clustering, and their phase transitions can have a percolative character.This volume presents experimental and theoretical work on these exciting new developments in condensed matter physics and materials science.
Author: Yakun Yuan
Publisher:
ISBN:
Category :
Languages : en
Pages :
Get Book Here
Book Description
Complex oxides present a fertile ground states of spin, lattice, orbital, and charge degree of freedom. The competition and interaction among different degrees of freedom provide a fascinating playground for fundamental scientific research as well as exploring applications in modern technologies. The scope of materials research has gone beyond understanding materials behaviors in ground states, and has extended to engineering new properties into materials and exploring possible hidden phases. There are static and dynamic approaches can be utilized to drive a material away from its ground state. Statically, by engineering complex oxides into heterostructures, the strain epitaxy effect can significantly alter the properties of the epitaxially grown films. In addition, tilt epitaxy promises an even more powerful route to directly control materials properties through a ubiquitous distortion in complex oxides. However, the characterization of tilt epitaxy is still challenging. The dynamic approach based on the idea of mode-selective pumping using ultrafast optical pulses, which can transiently drive a material away from its ground state by exciting a particular degree of freedom. Combining with delayed probe pulses, the dynamic trajectories of materials can be mapped out at femtosecond temporal resolution. Chapter 2 adopts the static approach following the scheme of tilt epitaxy. This chapter explores the paradigm of tilt epitaxy in thin films and demonstrates the non-destructively characterizing such epitaxy in three-dimensions for low symmetry complex tilt systems composed of light anions. More specifically, this chapter demonstrates that the interfacial tilt epitaxy can transform ultrathin calcium titanate, a non-polar earth-abundant mineral, into high-temperature polar oxides that last above 900 K. The comprehensive picture of octahedral tilts and polar distortions is revealed by reconstructing the three-dimensional electron density maps across film-substrate interfaces with atomic resolution using coherent Bragg rod analysis. The results are complemented with aberration-corrected transmission electron microscopy, film superstructure reflections, and are in excellent agreement with density functional theory. The study could serve as a broader template for non-destructive, three-dimensional atomic resolution probing of complex low symmetry functional interfaces. Chapter 3 turns to dynamic modulation the ground state of Ca3Ru2O7, which exhibits a rich phase diagram including two magnetic transitions (TN=56 K and TC=48 K) with the appearance of an insulating-like pseudogap (at TC). In addition, there is a crossover back to metallic behavior at T*=30 K, the origin of which is still under debate. This chapter applies ultrafast optical pump optical probe spectroscopy to investigate quasi-particle dynamics as a function of temperature in this enigmatic quantum material. Two dynamical processes are identified, both of which are influenced by the onset of the pseudogap. This includes electron-phonon relaxation and, below TC, the onset of a phonon bottleneck hindering the relaxation of quasiparticles across the pseudogap. A gap-modified two-temperature model is introduced to describe the temperature dependence of electron-phonon thermalization, and use the Rothwarf-Taylor to model the phonon bottleneck. In conjunction with density functional theory, the experimental results synergistically reveal the origin of the T-dependent pseudogap. Further, the data and analysis indicate that T* emerges as a natural consequence of T-dependent gapping out of carriers, and does not correspond to a separate electronic transition. The results highlight the value of low fluence ultrafast optics as a sensitive probe of low energy electronic structure, thermodynamic parameters, and transport properties of quantum materials. Chapter 4 serves as a comprehensive technical review of coherent Bragg rods analysis. This chapter starts with a mathematical description of the COBRA method and related iteration algorithms. Technical details being discussed includes: experimental data processing, symmetry application, convergence discussion, choice of boundary condition, sample thickness, and error analysis. The newly developed MATLAB routines for COBRA is introduced in appendix. Chapter 5 is a summary of the thesis and contains possible future directions.
Author: Yuan-Hua Lin
Publisher: John Wiley & Sons
ISBN: 3527341978
Category : Technology & Engineering
Languages : en
Pages : 280
Get Book Here
Book Description
The first book of its kind?providing comprehensive information on oxide thermoelectrics This timely book explores the latest research results on the physics and materials science of oxide thermoelectrics at all scales. It covers the theory, design and properties of thermoelectric materials as well as fabrication technologies for devices and their applications. Written by three distinguished materials scientists, Oxide Thermoelectric Materials reviews: the fundamentals of electron and phonon transport; modeling of thermoelectric modules and their optimization; synthetic processes, structures, and properties of thermoelectric materials such as Bi2Te3- and skutterudite-based materials and Si-Ge alloys. In addition, the book provides a detailed description of the construction of thermoelectric devices and their applications. -Contains fundamentals and applications of thermoelectric materials and devices, and discusses their near-future perspectives -Introduces new, promising materials and technologies, such as nanostructured materials, perovskites, and composites -Paves the way for increased conversion efficiencies of oxides -Authored by well-known experts in the field of thermoelectrics Oxide Thermoelectric Materials is a well-organized guidebook for graduate students involved in physics, chemistry, or materials science. It is also helpful for researchers who are getting involved in thermoelectric research and development.
Author: Ajay Kumar Yadav
Publisher:
ISBN:
Category :
Languages : en
Pages : 294
Get Book Here
Book Description
It is historically proven that artificial heterostructures are of paramount importance for both fundamental research and technological application. One distinguishable example is superlattices and quantum-well heterostructures of conventional semiconductors (III-V). Several fundamental observations such as two-dimensional electron gas, quantum confinement effect, quantum Hall effect and fractional quantum Hall effect, were first realized in artificial heterostructures of conventional semiconductors. On the technological front, artificial heterostructures of conventional semiconductors were found to revolutionize optoelectronic and high-speed electronic industry. Given the capability of artificial heterostructures to enable new physical phenomena, with an appropriate choice of material system, these heterostructures hold the potential to uncover hidden physical phenomena and exotic phases, which are otherwise not observed in bulk systems. One choice of such a system could be a strongly correlated material where the presence of strong electronic correlations has been known to enable unique electronic and magnetic properties. Complex oxides, in particular, are known to exhibit a strong interaction between various degrees of freedom available such as spin, charge, orbital and lattice degree, and thus offer a suitable choice of material system. In literature, one can find plenty of examples from different areas of research such as superconductivity, magnetism, ferroelectricity and thermoelectricity, where artificial superlattices led to the observation of fundamentally different behavior, compared to bulk superlattice constituents. These artificial superlattices and heterostructures continue to be the most promising candidate for exploring new phenomena and enhancing physical properties in complex oxide material systems. In this dissertation, artificial superlattices of complex oxides were synthesized in a thin-film geometry to enable the observation of fundamentally new physical phenomena, compared to their bulk counterparts, in few selected areas of investigation. First, I will present the experimental results on heat transport across superlattice structures composed of insulating perovskite oxides. The measured thermal conductivity of these artificial superlattices exhibited a unique phonon transport, i.e. coherent phonon transport, phenomenon that is extremely rare to observe in bulk form. The key element for enabling the coherent transport of phonon in these superlattice systems is the range of phonon wavelengths, which carry most of the heat in the material. The critical range being between 1-3 nanometers, the size of the system needs to reduce to this length scale in order to observe the effect of the wave nature of phonons on heat transport. Thus, superlattice structures offer an ideal candidate to search for this novel phenomenon. Several theoretical studies predicted the existence of these phenomena, but the experimental evidence of their existence remained largely absent or inconclusive. By synthesizing the superlattice of perovskite oxides, I’ve observed unambiguous evidence of the coherent transport of phonons at short-period superlattices of SrTiO3-CaTiO3 and BaTiO3-SrTiO3. In contrast to conventional heat conduction mechanisms, where phonon transport can be described by energy-carrying particles, the uniqueness of this phenomenon is highlighted by the fact that the wave aspect of phonons needs to be invoked to understand their transport behavior. After observing the wave nature of phonons in dictating heat conduction across periodic superlattices, other artificial heterostructures were studied to understand the nature of coherent phonon transport at the superlattice interfaces. Designed superlattice-like sequences, where the structural order can be controlled from a periodic sequence to a completely random sequence, were synthesized to further understand the role of the coherent scattering of phonons in thermal transport across superlattice structures. Next, I will discuss the experimental observation of another unique phenomenon, which was enabled by artificial superlattices of complex oxides in a different subject of research, i.e. ferroelectricity. Several theoretical studies on nanostructured ferroelectric systems such as nanodisc, nanocomposites, superlattices etc., predicted the stabilization of novel ferroelectric ground states. A number of different topologies of electrical polarization such as vortices and skyrmions, were predicted in ferroelectric nanostructures, which showed a strong resemblance to spin topologies such as skyrmion, merons etc. found in magnetic systems. Experimental confirmation for the existence of these exotic polarization states, however, remained absent. By leveraging the competition among charge, orbital and lattice degrees of freedom in superlattices of a paraelectric (SrTiO3) and ferroelectric (PbTiO3) material, vortex-antivortex structures of electrical polarization were stabilized in ferroelectric (PbTiO3) layers of PbTiO3-SrTiO3 superlattice. Only for a narrow range of superlattice periods, the polarization vortices are stabilized with a balance between one gradient energy associated with the non-uniform polarization profile of the vortex structure and the other’s electrostatic and elastic energies associated with depolarization fields and epitaxial constraints from the substrate, respectively. In the last section, I will describe unique and unusual phenomena associated with the existence of polarization vortices in paraelectric/ferroelectric superlattices. Superlattices of PbTiO3-SrTiO3 with varying periodicity showed a rich spectrum of characteristically different ferroelectric domains. Specifically, in the short-period regime, domain size was observed to evolve with a negative scaling coefficient, which is unusual for typical ferroelectrics. When the superlattice periodicity was increased, the average domain size decreased, suggesting an opposite behavior to the universal Kittel’s Law, where in the latter, an increase in ferroelectric thickness leads to an increase in the average domain size. Second, I will present intriguing results on the fundamental characteristics of polarization vortices as revealed from X-ray circular dichroism studies. The finite difference in absorption spectra of left-circular vs. right-circular polarized light from vortex structures, suggested that vortex-antivortex arrays are chiral in nature. The presence of chirality in polarization vortex structures is a characteristically different behavior compared to bulk ferroelectric systems where uniformly polarized regions are expected to exhibit a linear X-ray dichroism (i.e. a difference in the absorption spectra of linearly polarized light in a direction parallel and perpendicular to ferroelectric order). Lastly, a possibility of manipulating phonon dispersion using vortex ordering or vortex “lattice” is discussed, along with a hypothesis of inducing localization in propagative phonons.
