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A Systematic Transport and Thermodynamic Study of Heavy Transition Metal Oxides with Hexagonal StructureButrouna, Kamal H 01 January 2014 (has links)
There is no apparent, dominant interaction in heavy transition metal oxides (TMO), especially in 5d-TMO, where all relevant interactions are of comparable energy scales, and therefore strongly compete. In particular, the spin-orbit interaction (SOI) strongly competes with the electron-lattice and on-site Coulomb interaction (U). Therefore, any tool that allows one to tune the relative strengths of SOI and U is expected to offer an opportunity for the discovery and study of novel materials. BaIrO3 is a magnetic insulator driven by SOI whereas the isostructural BaRuO3 is a paramagnetic metal. The contrasting ground states have been shown to result from the critical role of the strong SOI in the iridate. This dissertation thoroughly examines a wide array of newly observed novel phenomena induced by adjusting the relative strengths of SOI and U via a systematic chemical substitution of the Ru4+(4d4) ions for Ir4+(5d5) ions in BaIrO3, i.e., in high quality single crystals of BaIr1-xRuxO3(0.0 < x < 1.0) . Our investigation of structural, magnetic, transport and thermal properties reveals that Ru substitution directly rebalances the competing energies so profoundly that it generates a rich phase diagram for BaIr1-xRuxO3 featuring two major effects: (1) Light Ru doping (0 < x < 0.15) prompts a simultaneous and precipitous drop in both the magnetic ordering temperature TC and the electrical resistivity, which exhibits metal-insulator transition at around TC. (2) Heavier Ru doping (0.41 < x < 0.82) induces a robust metallic and spin frustration state. For comparison and contrast, we also substituted Rh4+(4d5) ions for Ir4+(5d5) ions in BaIrO3, i.e. BaIr1-xRhxO3(0.0 < x < 0.10), where Rh only reduces the SOI, but without altering the band filling. Hence, this system remains tuned at the Mott instability and is very susceptible to disorder scattering which gives rise to Anderson localization.
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Ballistic Magnetotransport and Spin-Orbit Interaction InSb and InAs Quantum WellsPeters, John Archibald 11 September 2006 (has links)
No description available.
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Optical Control and Spectroscopic Studies of Collisional Population Transfer in Molecular Electronic StatesPan, Xinhua January 2017 (has links)
The quantum interference effects, such as the Autler-Townes (AT) effect and electromagnetically induced transparency (EIT) applied to molecular systems are the focus of this Dissertation in the context of high resolution molecular spectroscopy. We demonstrate that the AT effect can be used to manipulate the spin character of a spin-orbit coupled pair of molecular energy levels serving as a \textit{gateway} between the singlet and triplet electronic states. We demonstrate that the singlet-triplet mixing characters of the \textit{gateway} levels can be controlled by manipulating the coupling laser \textit{E} field amplitude. We observe experimentally the collisional population transfer between electronic states $G^1\Pi_g (v=12, J=21, f)$ and $1^3\Sigma _g^-(v=1, N=21, f)$ of $^7$Li$_2$. We obtain the Stern-Vollmer plot according to the vapor pressure dependence of collisional transfer rate. The triplet fluorescence from the mixed \textit{gateway} levels to the triplet $b^3\Pi_u(v'=1,J'= / Physics
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Spin Polarized Transport in Nanoscale DevicesPramanik, Sandipan 01 January 2006 (has links)
The ultimate goal in the rapidly burgeoning field of spintronics is to realize semiconductor-based devices that utilize the spin degree of freedom of a single charge carrier (electron or hole) or an ensemble of such carriers to achieve novel and/or enhanced device functionalities such as spin based light emitting devices, spin transistors and femto-Tesla magnetic field sensors. These devices share a common feature: they all rely on controlled transport of spins in semiconductors. A prototypical spintronic device has a transistor-like configuration in which a semiconducting channel is sandwiched between two contacts (source and drain) with a gate electrode sitting on top of the channel. Unlike conventional charge-based transistors, the source electrode of a spin transistor is a ferromagnetic (or half-metallic) material which injects spin polarized electrons in the channel. During transit, the spin polarizations of the electrons are controllably rotated by a gate electric field mediated spin-orbit coupling effect. The drain contact is ferromagnetic (or half-metallic) as well and the transmission probability of an electron through this drain electrode depends on the relative orientation of electron spin polarization and the (fixed) magnetization of the drain. When the spins of the electrons are parallel to the drain magnetization, they are transmitted by the drain resulting in a large device current (ON state of spin FET). However, these electrons will be completely blocked if their spins are antiparallel to the drain magnetization, and ideally, in this situation device current will be zero (OFF state of spinFET). Thus, if we vary the gate voltage, we can modulate the channel current by controlling the spin orientations of the electrons with respect to the drain magnetization. This is how transistor action is realized (Datta-Das model). However, during transport, electrons' velocities change randomly with time due to scattering and hence different electrons experience different spin-orbit magnetic fields. As a result, even though all electrons start their journey with identical spin orientations, soon after injection spins of different electrons point along different directions in space. This randomization of initial spin polarization is referred to as spin relaxation and this is detrimental to the spintronic devices. In particular, for Datta-Das transistor, this will lead to inefficient gate control and large leakage current in the OFF state of the spinFET. The aim of this work is to understand various spin relaxation processes that are operative in semiconductor nanostructures and to indicate possible ways of minimizing them. The theoretical aspect of this work (Chapters 2-5) focuses on the D'yakonov-Perel' process of spin relaxation in a semiconductor quantum wire. This process of spin relaxation occurs because during transport electron spin precesses like a spinning top about the spin-orbit magnetic field. We show that the conventional drift-diffusion model of spin transport, which has been used extensively in literature, completely breaks down in case of a quantum confined system (e.g. a quantum wire). Our approach employs a semi-classical model which couples the spin density matrix evolution with the Boltzmann transport equation. Using this model we have thoroughly studied spin relaxation in a semiconductor quantum wire and identified several inconsistencies of the drift-diffusion formalism.The experimental side of this work (Chapters 6-8) deals with two different issues: (a) performing spin transport experiments in order to extract spin relaxation length and time in various materials (e.g. Cu, Alq3) under one-dimensional confinement, and (b) measurement of the ensemble spin dephasing time in self-assembled cadmium sulfide quantum dots using electron spin resonance technique. The spin transport experiment, as described in Chapter 7 of this dissertation, shows that the spin relaxation time in organic semiconductor (Alq3) is extremely long, approaching a few seconds at low temperatures. Alq3 is the chemical formula of tris- 8 hydroxy-quinoline aluminum, which is a small molecular weight organic semiconductor. This material is extensively used in organic display industry as the electron transport and emission layer in green organic light emitting diodes. The long spin relaxation time in Alq3 makes it an ideal platform for spintronics. This also indicates that it may be possible to realize spin based organic light emitting diodes which will have much higher internal quantum efficiency than their conventional non-spin counterparts. From spin transport experiments mentioned above we have also identified Elliott-Yafet mode as the dominant spin relaxation mechanism operative in organic semiconductors. Electron spin resonance experiment performed on self-assembled quantum dots (Chapter 8) allows us to determine the ensemble spin dephasing time (or transverse spin relaxation time) of electrons confined in these systems. In quantum dots electrons are strongly localized in space. Surprisingly, the ensemble spin dephasing time shows an increasing trend as we increase temperature. The most likely explanation for this phenomenon is that spin dephasing in quantum dots (unlike quantum wells and wires) is dominated by nuclear hyperfine interaction, which weakens progressively with temperature. We hope that our work, which elaborates on all of the above mentioned topics in great detail, will be a significant contribution towards the current state of knowledge of subtle spin-based issues operative in nanoscale device structures, and will ultimately lead to realization of novel nano-spintronic devices.
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Supraconductivité en présence de forts effets paramagnétique et spin-orbiteKonschelle, François 02 October 2009 (has links)
L'état supraconducteur étant un condensat de paires de Cooper constitué d'électrons de moments et de spins opposés, il peut être fortement influencé par des effets de spin. Au cours de cette thèse, nous étudions l'effet d'un fort champ d'échange et d'un effet spin-orbite de type Rashba sur les propriétés supraconductrices. Dans une première partie, on étudie les effets associés à l'interaction entre supraconductivité et fort champ d'échange, se caractérisant par une transition de phase vers un état supraconducteur inhomogène découvert par Fulde, Ferrell, Larkin et Ovchinnikov (FFLO). On étudie tout particulièrement les fluctuations supraconductrices à l'approche de la transition de phase. On montre que ces fluctuations peuvent servir de révélateur à cette phase. Notamment, la capacité calorifique et la paraconductivité divergent de façon caractéristique à la transition vers un état modulé. On décrit également comment les effets paramagnétiques modifient les fluctuations de l'aimantation, annulant la réponse diamagnétique ou produisant des oscillations entre réponse para- et dia-magnétique. La seconde partie est dévolue aux jonctions supraconducteur-ferromagnétique (S/F). Dans les jonctions Josephson S/F/S, le champ d'échange donne lieu à des oscillations du courant critique en fonction de la longueur de la jonction, charactérisées par une alternance des états 0 et . On prédit une transition entre les états 0 et induite par la température, même dans la limite ballistique. Dans cette limite ballistique, on montre également que le courant de Josephson s'atténu sous la forme de lois de puissance en fonction de la longueur de la jonction, alors que le cas diffusif présente une atténuation exponentielle. On étudie ensuite la seconde harmonique de la relation courant-phase en présence d'une faible quantité d'impuretés. La dernière partie traite des effets de proximité lorsque les deux effets paramagnétique et spin-orbite sont présents dans une jonction Josephson. On montre que l'association d'une interaction Rashba et d'un champ d'échange induit un couplage direct entre les ordres magnétique et supraconducteur. En particulier, ce couplage permet de générer toute la dynamique magnétique par l'application d'une simple tension électrique. / The superconducting state being a Cooper pair condensate built on opposite spin and momentum electrons, it can be strongly influenced by any spin effect. In this thesis, we investigate the roles of strong paramagnetic and spin-orbit effects on superconducting properties. In a first part, the interplay between paramagnetic effect and bulk superconductivity is studied, leading to the modulated Fulde, Ferrell, Larkin and Ovchinnikov phase (FFLO phase). We focus on superconducting fluctuations near to the FFLO state. We show that these fluctuations can serve as a smoking gun for this phase. Noticeably, the fluctuation heat capacity and paraconductivity diverge in a characteristic way when approaching the phase transition towards a modulated state. Moreover, the fluctuation induced magnetization is predicted to be drastically quenched or to oscillate between dia- and para-magnetic responses. The second part is devoted to superconductor-ferromagnetic (S/F) junctions. In S/F/S Josephson junctions, the exchange field is responsible for the critical current oscillation, characterized by alternative 0- and -states, with respect to the junction length. We predict a temperature induced (0-) state transition, even in the ballistic case. Moreover, the ballistic case exhibits some power law decays of the Josephson current, in contrast to the exponentially decaying current in dirty limit. The moderately dirty limit is then investigated, and the second harmonic of the current-phase relation is established. The last part deals with proximity effects when both paramagnetic and spin-orbit interactions are present in a Josephson junction. We show that the association of both Rashba interaction and exchange field induces a direct coupling between magnetic and superconducting orders. Particularly, this coupling generates the complete magnetization dynamics by applying an appropriate d.c. voltage.
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Relativistická teorie elektronového transportu v magnetických vrstvách / Relativistic Theory of Electron Transport in Magnetic LayersSýkora, Rudolf January 2012 (has links)
Title: Relativistic Theory of Electron Transport in Magnetic Layers Author: Rudolf Sýkora Department / Institute: Institude of Theoretical Physics Supervisor of the doctoral thesis: doc. RNDr. Ilja Turek, DrSc., Department of Condensed Matter Physics Abstract: We review the density-functional theory (DFT) in detail using the Levy Lieb ap- proach. The Kohn Sham scheme is discussed, starting from the simplest spinless non- relativistic case, then including spin and considering potential spin magnetism, and finally deriv- ing the full Kohn Sham Dirac relativistic scheme. The Linear Muffin-Tin Orbital (LMTO) method for electronic-structure calculation is presented, together with mentioning the necessary changes to include the spin-orbit (SO) interaction effects to an otherwise scalar-relativistic (SR) theory. Derivation of an electronic-conductance formula for a layered system is given, based on the Landauer scattering picture and using simple non-equilibrium Green functions. The formal- ism is applied to layered metallic systems of light elements Co, Ni, Cu elements, and to layered systems with a tunnelling barrier, Fe/MgO/Ag and Fe/GaAs/Ag. The effects of the SO interac- tion on the Giant Magnetoresistance (GMR) ratio and/or the Tunnelling Anisotropy Magnetore- sistance (TAMR) for these systems are discussed....
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Spin-Dependent Optical Phenomena: Fundamentals and ApplicationsVázquez Lozano, Juan Enrique 24 May 2021 (has links)
Tesis por compendio / [ES] Al igual que la masa o la carga, el espín es una propiedad física fundamental que, típicamente, aparece en la descripción de los sistemas cuánticos. Más allá de sus importantes implicaciones teóricas, el creciente avance de la tecnología y el desarrollo de los dispositivos hacia escalas cada vez más pequeñas ha favorecido el surgimiento de multitud de aplicaciones que involucran al espín, entre las cuales se destaca la espintrónica; una nueva forma de electrónica en la que, además de la carga, también se explotan los grados de libertad otorgados por el espín del electrón. Por supuesto, el espín no es exclusivo de los electrones, está presente en todas las partículas elementales, y por ende, en los fotones. En este caso, y a diferencia de lo que ocurre con los electrones, existe una correspondencia clásica que relaciona el espín del fotón con los estados de polarización circular de la luz. Por lo tanto, en nano-óptica y en fotónica, los fenómenos basados en el espín se refieren, grosso modo, a aquellos que son fuertemente dependientes de la polarización circular de la luz. En este marco general, uno de los ejemplos más preponderantes se halla en la interacción espín-órbita. En su versión óptica establece que, bajo ciertas condiciones, es posible que exista una influencia mutua entre el estado de polarización (espín) y la propagación (órbita) de la luz. A pesar de su carácter ubicuo en todos los procesos ópticos básicos, sus efectos son muy débiles, y su manifestación se restringe a la nanoescala, lo cual dificulta su observación e identificación. En este mismo contexto, otro concepto heredado del formalismo cuántico que tiene análogo fotónico directo es la quiralidad óptica; una propiedad dinámica local que, de alguna manera, permite cuantificar escalarmente el espín de un campo óptico. Aparte de su controvertido significado físico y su estrecho vínculo con los sistemas plasmónicos y los metamateriales, como amplificadores de sus efectos, su principal característica fundamental es que, para los campos ópticos en el vacío, es una cantidad conservada. En esta tesis se ahonda teóricamente en los fundamentos básicos de estas características fotónicas. Específicamente, se demuestra analíticamente que la interacción espín-órbita es un fenómeno que surge natural y necesariamente en la nanoescala. Sobre esta base se expone un formalismo para extender la excitación unidireccional de campo cercano más allá de la aproximación dipolar, lo cual facilita su observación y mejora las propiedades de acoplo. Por otra parte, se analiza el concepto de la quiralidad óptica, originalmente definida en el vacío, y se generaliza a cualquier tipo de medio, incluyendo sistemas altamente dispersivos. Asimismo, se exploran diferentes configuraciones que permitan implementar las principales funcionalidades quirópticas (sensado y espectroscopía) en plataformas de fotónica integrada. Además de su potencial para aplicaciones, este estudio tiende un puente para abordar clásicamente propiedades y efectos que tradicionalmente son de tipo cuántico. / [CA] Igual que la massa o la càrrega, l'espín és una propietat física fonamental que, típicament, apareix en la descripció dels sistemes quàntics. Més enllà de les seves importants implicacions teòriques, el creixent avanç de la tecnologia i el desenvolupament dels dispositius cap a escales cada vegada més petites ha afavorit el sorgiment de multitud d'aplicacions que involucren l'espín, entre les quals es destaca l'espintrònica; una nova forma d'electrònica en què, a més de la càrrega, també s'exploten els graus de llibertat atorgats per l'espín de l'electró. Per descomptat, l'espín no és exclusiu dels electrons, és present en totes les partícules elementals, i per tant, en els fotons. En aquest cas, i a diferència del que passa amb els electrons, hi ha una correspondència clàssica que relaciona l'espín del fotó amb els estats de polarització circular de la llum. Per tant, en nano-òptica i en fotònica, els fenòmens basats en l'espín es refereixen, grosso modo, a aquells que són fortament dependents de la polarització circular de la llum. En aquest marc general, un dels exemples més preponderants es troba en la interacció espín-òrbita. En la seva versió òptica estableix que, sota certes condicions, és possible que hi hagi una influència mútua entre l'estat de polarització (espín) i la propagació (òrbita) de la llum. Malgrat el seu caràcter ubic en tots els processos òptics bàsics, els seus efectes són molt febles, i la seva manifestació es restringeix a la nanoescala, la qual cosa dificulta la seva observació i identificació. En aquest mateix context, un altre concepte heretat del formalisme quàntic que té anàleg fotònic directe és la quiralitat òptica; una propietat dinàmica local que, d'alguna manera, quantifica escalarment l'espín d'un camp òptic. A banda del seu controvertit significat físic i el seu estret vincle amb els sistemes plasmònics i els metamaterials, com amplificadors dels seus efectes, la seva principal característica fonamental és que, per als camps òptics en el buit, és una quantitat conservada. Des d'un enfocament teòric, aquesta tesi aprofundeix en els fonaments bàsics d'aquestes característiques fotòniques. Específicament, es demostra analíticament que la interacció espín-òrbita és un fenomen que sorgeix natural i necessàriament en la nanoescala. Sobre aquesta base s'exposa un formalisme per estendre l'efecte d'excitació unidireccional de camp pròxim més enllà de l'aproximació dipolar, la qual cosa facilita la seva observació i millora les propietats d'acoblo. D'altra banda, s'analitza el concepte de la quiralitat òptica, originalment definida en el buit, i es generalitza a qualsevol tipus de mitjà, incloent sistemes altament dispersius. Així mateix, s'exploren diferents configuracions que permetin implementar les principals funcionalitats quiròptiques (sensat i espectroscòpia) en plataformes de fotònica integrada. A més del seu potencial per a aplicacions, aquest estudi tendeix un pont per abordar clàssicament propietats i efectes tradicionalment quàntics. / [EN] Just like mass or charge, spin is a fundamental physical property that, typically, appears in the description of quantum systems. Beyond its important theoretical implications, the rapid advance of technology along with the relentless trend toward the development of devices at increasingly smaller scales have boosted the occurrence of a wide range of applications involving spin, among which is highlighted the spintronics; a novel form of electronics which, besides the charge, also exploits the degrees of freedom provided by the electron spin. Of course, the spin is not exclusive to electrons, but is actually present in all the elementary particles, and therefore in photons. In such a case, and unlike what happens with electrons, there exists a direct classical correspondence relating the spin of photons with the circular polarization states of light. Thus, in nano-optics and photonics, spin-dependent phenomena are broadly referred to as those that strongly rely upon the circular polarization of light. Within this general framework, one of the most preponderant examples is found in the spin-orbit interaction. In its optical version, it states that, under certain conditions, it is possible that there exists a mutual influence between the state of polarization (spin) and the propagation (orbit) of light. Despite its ubiquitous character in all basic optical processes, its effects are very weak, and its manifestation is restricted at the nanoscale, thereby hindering its observation and identification. In this same context, another concept somehow inherited from the quantum formalism with a direct photonic analogue is the optical chirality; a local dynamical property that, in a way, allows one to quantifying scalarly the spin of an optical field. Apart from its controversial physical meaning and its close relationship with plasmonic systems and metamaterials, often regarded as chiral enhancers, its main feature is that, for optical fields in the vacuum, it is a conserved quantity. From a theoretical standpoint, this thesis delves into the basics of these photonic traits. Specifically, it is analytically demonstrated that the spin-orbit interaction is indeed a phenomenon that naturally and necessarily emerges at the nanoscale. Building on this, it is addressed a formalism to extend the effect of near-field unidirectional excitation beyond the dipolar approximation, thus facilitating its observation and improving the coupling performance. On the other side, the optical chirality, originally put forward for electromagnetic fields in vacuum, is thoroughly analyzed and generalized to any arbitrary medium, including highly dispersive systems. Furthermore, different configurations for implementing the main chiroptical functionalities (sensing and spectroscopy) in integrated photonic platforms are explored. Besides its potential for applications, this study lays a bridge to classically approach features and effects which are traditionally quantum-like. / This work was supported by fundings from Ministerio de Economía y Competitividad of Spain (MINECO) under Contract No.TEC2014-51902-C2-1-R. and by ERC Starting Grant No. ERC-2016-STG-714151-PSINFONI. This work was also partially supported by funding from the European Commission Project THOR H2020-EU-829067. / Vázquez Lozano, JE. (2021). Spin-Dependent Optical Phenomena: Fundamentals and Applications [Tesis doctoral]. Universitat Politècnica de València. https://doi.org/10.4995/Thesis/10251/166775 / Compendio
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Magnetic Interactions in Systems with Strong Spin-Orbit CouplingEldeeb, Mohamed Sabry 09 July 2024 (has links)
In the context of the search and tuning for novel magnetic materials, transition metal compounds exhibit remarkable features where the spin-orbit interaction is crucial. The collective interactions between various effects, like spins and charges, create different classes of unique magnetic systems. For heavy transition-metal compounds, the strength of spin-orbital coupling is enhanced. The jeff. = 1/2 Mott insulating state emerges from the combination of the spin-orbit interaction and the electronic correlations. The quantum-chemistry methods are employed in this thesis to investigate single- and two-site magnetic interactions of the selected transition-metal compounds. We also provide different estimations for the single- and two-site magnetic interactions based on the level of calculation accuracy.
In this thesis, we apply ab initio quantum-chemistry methods to explore the electronic and magnetic properties of several d/f compounds. The thesis structure is as follows:
In Chapter 1, the introduction of the thesis provides a short discussion of the electronic correlations and magnetism in transition metal compounds. In Chapter 2, the fundamentals of the quantum chemistry wavefunction-based approach are covered. This chapter gives an overview of the applied methods in this thesis.
In Chapter 3, we discuss the quantum chemistry approach to investigate the material candidates to host Kitaev physics. The technique to obtain the strength of two-site magnetic couplings, including the Kitaev coupling, is discussed in-depth.
In Chapter 4, we apply the technique, which is described in Chapter 3, to investigate the two-site magnetic interactions in the H3LiIr2O6, and Cu2IrO2 compounds as Kitaev candidates. The two-site magnetic couplings are reported in these compounds.
In Chapter 5, we use quantum chemistry methods to investigate the on-site electronic and magnetic properties in the KCeO2 compound where 4f1 Ce3+ ions form a triangular two-dimensional lattice with sites of effective spin-1/2. Similar ytterbiumbased delafossites had been investigated as candidates for quantum spin liquid ground states. The absence of ordinary magnetic order is characteristic of quantum spinliquid states where quantum entanglements and fractionalized excitations are enriched.
In Chapter 6, the magnetic properties of Co 3d8 ions doped in the Li3N crystalline solid are discussed. The results of the quantum chemistry investigation are been set side by side along with the experiment’s results. The Co ion in such a rare environment gives rise to single-site magnetism of an easy-plane anisotropy.:Table of Contents . . . . . . . . . . . . . . . . . . . . . . iv
List of Figures . . . . . . . . . . . . . . . . . . . . . . . . .vi
Abstract . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .i
Acknowledgements . . . . . . . . . . . . . . . . . . . . . .iii
1 Introduction . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .1
1.1 Electronic correlations and magnetism in transition metal compounds ...........1
1.2 Thesis outline . . . . . . . . . . . . . . . . . . . . . . . . . . . . 4
2 Quantum chemistry methodology . . . . . . . . . . . . . . . . .6
2.1 Introduction . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 7
2.2 Many-electron Hartree-Fock approximation . . . . . . . . . . . . . . . 9
2.3 Multi-configurational self-consistent field and multi-reference configuration
methods . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 13
2.4 Spin-orbit interaction and g-factors calculation . . . . . . . . . . . . . 15
2.5 Embedded cluster approach . . . . . . . . . . . . . . . . . . . . . . . 18
2.6 Summary . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 20
3 Quantum chemistry investigation of Kitaev material candidates . . . . . . . . . . .21
3.1 Introduction to the Kitaev model . . . . . . . . . . . . . . . . . . . . 23
3.2 Kitaev materials . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 28
3.3 Two-site quantum chemistry calculations . . . . . . . . . . . . . . . . 36
3.4 Effective Model of Two Spin-1/2 . . . . . . . . . . . . . . . . . . . . . 38
3.5 Non-canonical correspondence between two-site QC results and the
effective Hamiltonian . . . . . . . . . . . . . . . . . . . . . . . . . . . 43
3.6 Pseudospin coordinate system and canonical correspondence between
two-site QC results and the effective Hamiltonian . . . . . . . . . . . 51
3.7 Signs of the g-tensor in the Kitaev limit . . . . . . . . . . . . . . . . 53
3.8 Conclusion . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 58
4 Kitaev material candidates . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .60
4.1 Introduction . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 61
4.2 Details of QC calculations . . . . . . . . . . . . . . . . . . . . . . . . 64
4.3 QC investigation of H3LiIr2O6 . . . . . . . . . . . . . . . . . . . . . . 66
4.4 QC investigation of Cu2IrO3 . . . . . . . . . . . . . . . . . . . . . . . 75
4.5 Impact of local symmetries on the obtained sets of magnetic couplings ......... 82
4.6 Conclusion . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 88
5 Ce ions in two-dimensional triangular spin-1/2 lattices . . . . . . . . . . . . . . . . . . . . 89
5.1 Spin-1/2 frustrated triangular lattice . . . . . . . . . . . . . . . . . . 90
5.2 Correlated 4f -compounds as frustrated triangular lattices . . . . . . 94
5.3 Crystal structure of KCeO2 . . . . . . . . . . . . . . . . . . . . . . . 95
5.4 QC results for the electronic structure of Ce3+ ions in KCeO2 . . . . 100
5.5 The competition of SOC and crystal field splittings in KCeO2 . . . . 102
5.6 Chapter summary . . . . . . . . . . . . . . . . . . . . . . . . . . . . 108
6 Co-ion substitutes with linear coordination in Li3N . . . . . . . . . . . . . . . . . . . . . . 109
6.1 Introduction . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 110
6.2 Crystal structure of Li2(Li(1−x)Cox)N and spectroscopic measurements .......112
6.3 QC computational details . . . . . . . . . . . . . . . . . . . . . . . . 115
6.4 Ab initio QC investigation of the Co+ 3d8 electronic structure doped into Li3N . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 117
6.5 Chapter summary . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 128
Bibliography . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .135
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Spin-orbit interactions for steering Bloch surface waves with the optical magnetic field and for locally controlling light polarization by swirling surface plasmons / Interactions spin-orbite pour contrôler la directivité des ondes de surface de Bloch via le champ magnétique optique et pour contrôler et sonder localement l'état de polarisation de la lumièreWang, Mengjia 13 February 2019 (has links)
Ma thèse est consacrée aux nouveaux phénomènes nano-optiques et aux dispositifs basés sur l'interaction spin-orbite de la lumière (SOI). Tout d'abord, il a été démontré un SOI uniquement piloté par le champ magnétique de la lumière permettant de diriger avec précision les ondes de surface de Bloch, offrant ainsi une nouvelle manifestation du champ magnétique optique. Ensuite, nous avons proposé et démontré le concept de nano-antenne plasmonique hélicoïdale à ondes progressives (TW-HPA), c’est-à-dire un fil hélicoïdal en or étroit alimenté optiquement par une nano-antenne dipolaire dans une configuration « end-firing ». Une telle nano-antenne a été démontrée comme la première optique de polarisation sublongueur d’onde. L’agencement de TW-HPAs à l’échelle de quelques microns a permis de convertir « à la carte » un faisceau polarisé linéairement en une distribution de faisceaux directifs présentant des polarisations différentes définies de façon déterministe par la géométrie et les dimensions des nano-antennes. Par le biais d’un couplage en champ proche de quatre nano-antennes à hélicités opposées, nous avons obtenus une optique sublongueur d’onde permettant un degré de liberté dans le contrôle de la polarisation qui est interdit avec les composants et méthodes classiques basées sur l’exploitation de matériaux biréfringents ou dichroïques, ou de métamatériaux imitant ces propriétés. / My thesis is devoted to novel nano-optical phenomena and devices based on spin-orbit interaction (SOI) of light. First, magnetic spin-locking, i.e., an SOI solely driven by the magnetic field of light, is demonstrated with Bloch surface waves. It provides a new manifestation of the magnetic light field. Then, we propose and demonstrate the concept of traveling-wave plasmonic helical antenna (TW-HPA), consisting of a narrow helical gold-coated wire non-radiatively fed with a dipolar nano-antenna. By swirling surface plasmons, the TW-HPA combines subwavelength illumination and polarization transformation. The TW-HPA is demonstrated to radiate on the subwavelength scale almost perfectly circularly polarized optical waves upon illumination with linearly polarized light. With this subwavelength plasmonic antenna, we developed strongly integrated arrays of point-light emissions of opposite handedness and tunable intensities. Finally, by coupling two couples of TW-HPAs of opposite handedness, we obtained new polarization properties so far unattainable.
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Spin-orbit interaction in quantum dots and quantum wires of correlated electrons - A way to spintronics? / Spin-Bahn-Wechselwirkung in Quantenpunkten und Quantendrähten korrelierter Elektronen - Ein Weg Richtung Spintronik?Birkholz, Jens Eiko 06 October 2008 (has links)
No description available.
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