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Some contributions in probability and statistics of extremes.Kratz, Marie 15 November 2005 (has links) (PDF)
Part I - Level crossings and other level functionals.<br />Part II - Some contributions in statistics of extremes and in statistical mechanics.
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Studies Of Electronic, Magnetic And Entanglement Properties Of Correlated Models In Low-Dimensional SystemsSahoo, Shaon 09 1900 (has links) (PDF)
This thesis consists of six chapters. The first chapter gives an introduction to the field of low-dimensional magnetic and electronic systems and relevant numerical techniques. The recent developments in molecular magnets are highlighted. The numerical techniques are reviewed along with their advantages and disadvantages from the present perspective. Study of entanglement of a system can give a great insight into the system. At the last part of this chapter a general overview is given regarding entanglement, its measures and its significance in studying many-body systems.
Chapter 2 deals with the technique that has been developed by us for the full symmetry adaptation of non-relativistic Hamiltonians. It is advantageous both computationally and physically/chemically to exploit both spin and spatial symmetries of a system. It has been a long-standing problem to target a state which has definite total spin and also belongs to a definite irreducible representation of a point group, particularly for non-Abelian point groups. A very general technique is discussed in this chapter which is a hybrid method based on valence-bond basis and the basis of the z-component of the total spin. This technique is not only applicable to a system with arbitrary site spins and belonging to any point group symmetry, it is also quite easy to implement computationally. To demonstrate the power of the method, it is applied to the molecular magnetic system, Cu6Fe8, with cubic symmetry.
In chapter 3, the extension of the previous hybrid technique to electronic systems is discussed. The power of the method is illustrated by applying it to a model icosahedral half-filled electronic system. This model spans a huge Hilbert space (dimension 1,778,966) and is in the largest non-Abelian point group. All the eigenstates of the model are obtained using our technique.
Chapter 4 deals with the thermodynamic properties of an important class of single-chain magnets (SCMs). This class of SCMs has alternate isotropic spin-1/2 units and anisotropic high spin units with the anisotropy axes being non-collinear. Here anisotropy is assumed to be large and negative, as a result, anisotropic units behave like canted spins at low temperatures; but even then simple Ising-type model does not capture the essential physics of the system due to quantum mechanical nature of the isotropic units. A transfer matrix (TM) method is developed to study statistical behavior of this class of SCMs. For the first time, it is also discussed in detail that how weak inter-chain interactions can be treated by a TM method. The finite size effect is also discussed which becomes important for low temperature dynamics. This technique is applied to a real helical chain magnet, which has been studied experimentally.
In the fifth chapter a bipartite entanglement entropy of finite systems is studied using exact diagonalization techniques to examine how the entanglement changes in the presence of long-range interactions. The PariserParrPople model with long-range interactions is used for this purpose and corresponding results are com-pared with those for the Hubbard and Heisenberg models with short-range interactions. This study helps understand why the density matrix renormalization group (DMRG) technique is so successful even in the presence of long-range interactions in the PPP model. It is also investigated if the symmetry properties of a state vector have any significance in relation to its entanglement. Finally, an interesting observation is made on the entanglement profiles of different states, across the full energy spectrum, in comparison with the corresponding profile of the density of states.
The entanglement can be localized between two noncomplementary parts of a many-body system by performing local measurements on the rest of the system. This localized entanglement (LE) depends on the chosen basis set of measurement (BSM). In this chapter six, an optimality condition for the LE is derived, which would be helpful in finding optimal values of the LE, besides, can also be of use in studying mixed states of a general bipartite system. A canonical way of localizing entanglement is further discussed, where the BSM is not chosen arbitrarily, rather, is fully determined by the properties of a system. The LE obtained in this way, called the localized entanglement by canonical measurement (LECM), is not only easy to calculate practically, it provides a nice way to define the entanglement length. For spin-1/2 systems, the LECM is shown to be optimal in some important cases. At the end of this chapter, some numerical results are presented for j1 −j2 spin model to demonstrate how the LECM behaves.
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Hochfeld/Hochfrequenz-Elektronenspin-Resonanz an Übergangsmetallverbindungen mit starken elektronischen Korrelationen: Hochfeld/Hochfrequenz-Elektronenspin-Resonanz an Übergangsmetallverbindungen mit starken elektronischen KorrelationenSchaufuß, Uwe 02 September 2009 (has links)
Starke elektronische Korrelationen und die daraus resultierenden vielfältigen Phänomenen sind Gegenstand der modernen Festkörperphysik. Solche Korrelationen finden sich in den verschiedensten Systemen vom Isolator über die Halbleiter bis hin zu Metallen. In dieser Arbeit werden die durch Korrelationen hervorgerufenen Phänomene in zwei niederdimensionalen Übergangsmetalloxiden und zwei intermetallischen Verbindungen mithilfe der HF-ESR untersucht.
Die Elektronenspin-Resonanz (ESR) nutzt als lokale Messmethode den Spin der Elektronen als Sonde, um die magnetischen Eigenschaften im Umfeld des Elektrons und die Wechselwirkungen (WW) mit anderen Elektronen zu erforschen. Mit stärker werdenden Elektron-Elektron (EE)-Korrelationen kommt es (unter anderem) zu einer Verbreiterung der Resonanz, sodass, um die Resonanz zu beobachten, höhere
Frequenzen bzw. größere Felder als in kommerziellen ESR-Spektrometern erreichbar, nötig sind. Mit der in dieser Arbeit genutzten Hochfeld/Hochfrequenz-Elektronenspin-Resonanz (HF-ESR) mit einem frei durchstimmbaren Frequenzbereich von $\nu=\vu{20- 700}{GHz}$ kann speziellen Fragestellungen nachgegangen werden,
bei denen die Anregungsenergien im Bereich von $h\nu$ liegen oder Resonanz-Effekte bei hohen Felder beobachtet werden sollen.
CaCu$_2$O$_3$ zeigt die gleiche Kristallstruktur wie \chem{SrCu_2O_3}, einem Lehrbuchbeispiel für eine 2-beinige
Spin\textfrac{1}{2}-Leiter mit einem nichtmagnetischen Grundzustand und einer großen Spinlücke zum ersten angeregten Zustand. \chem{CaCu_2O_3} zeigt dagegen überraschenderweise einen antiferromagnetischen (AFM) Grundzustand mit einer relativ hohen Übergangstemperatur. Um der Ursache der AFM-Ordnung auf den
Grund zu gehen, wurde eine kombinierte Studie der Magnetisierung und der HF-ESR an einer Reihe von Zn-dotierten \chem{CaCu_2O_3} durchgeführt. Im Gegensatz zum Sr-Material sind die \chem{Cu_2O_3}-Leiter-Ebenen durch einen geringeren Sprossenwinkel leicht gewellt, desweiteren zeigt \chem{CaCu_2O_3} eine nichtstöchiometrische Zusammensetzung \chem{Ca_{1- x} Cu_{2+x}O_3}, mit einem Überschuss von Cu von $x\sim 0.16$ im nichtmagnetischen \chem{Cu^{1+}}-Zustand, welches auf Ca-Plätzen sitzt. Wir werden zeigen, dass (i) die Extra-Spins im undotierten Material \emph{nicht} in den Ketten sitzen, sondern auf regelmäßigen
Zwischengitterpositionen. Sie rekrutieren sich aus dem überschüssigen
\chem{Cu^{1+}}, dessen Position in der Nähe einer O-Fehlstelle instabil wird, sich verschiebt und den Zustand in ein magnetischen \chem{Cu^{2+}} ändert, (ii) dass durch die Position der Extra-Spins eine Kopplung übernächster Spin-Leitern zustande kommt, welche die Frustration der Spin-Leitern aufhebt und einen AFM-Grundzustand mit solch hoher Übergangstemperatur erlaubt und (iii) dass diese Position der Extra-Spins die zusätzliche schwache kommensurable Spinstruktur
erklären kann, die im AFM- Zustand neben der inkommensurablen Spinstruktur der Leiter-Spins beobachtet wurde.
Das einfach geschichtete Manganat \textbf{LaSrMnO$_4$} ist ein
zweidimensionaler Vertreter der Übergangsmetalloxide. In diesem Material gibt es starke Korrelationen zwischen dem orbitalen und dem magnetischen Freiheitsgrad, sodass die AFM-Ordnung unterhalb von $T_N\sim\vu{125}{K}$ mit einer ferro-orbitalen Ordnung der \chem{Mn^{3+}} $3d$-Orbitale einhergeht. Mithilfe der HF-ESR konnte die temperaturabhängige Mischung der $3d$-Orbitale direkt bestimmt und damit die Theorie der ferro-orbitalen Ordnung quantitativ bestätigt werden.
Im AFM geordneten Zustand, unterhalb von $T_\text{stat}\sim\vu{40}{K}&lt;T_N$ wurde eine starke feldabhängige Reduktion der Mikrowellen-Transmission beobachtet, deren Frequenzabhängigkeit ein direkter Hinweis auf ferromagnetische (FM) Polaronen ist, die durch die WW von zusätzlichen Ladungsträgern mit den AFM-geordneten Grundspins entstehen.
GdNi$_2$B$_2$C Die intermetallische Verbindungen der Nickelborkarbide $R\chem{Ni_2B_2C}$ ($R$ - Seltene Erdmetalle) zogen seit der Entdeckung von Supraleitung in einigen dieser Verbindungen große Aufmerksamkeit auf sich. Sie zeigen hochkomplexe magnetische Phasendiagramme mit einem Wechselspiel zwischen Supraleitung und der damit konkurrierenden AFM-Ordnung mit unterschiedlichsten Spinstrukturen. Ein Grund für diese Komplexität ist die starke magnetische Anisotropie, die durch die Aufspaltung des $J$-Multipletts der $f$-Orbitale der $R$ im Kristallfeld hervorgerufen wird. Das nicht supraleitende \chem{GdNi_2B_2C} erhielt als Modell-System viel Aufmerksamkeit, da \chem{Gd^{3+}} mit einer halbgefüllten $4f$-Schale keine magnetische Anisotropie zeigen sollte. Die vorgestellte ESR-Studie an \chem{GdNi_2B_2C} wird jedoch zeigen, dass dieser vermeintlich reine Spinmagnet eine ungewöhnlich
starke magnetische Anisotropie besitzt, die sich auf die hochkomplexe
Bandstruktur zurückführen lässt. Das Einbeziehen dieser Resultate in die Modellierung des Systems wird helfen, die Abweichungen zwischen Modell und Realität zu erklären.
YbRh$_2$Si$_2$ In diesem schwere-Fermionen-System, indem die
magnetischen Yb ($4f$) ein regelmäßiges Kondo-Gitter aufbauen, konkurrieren die EE-WW und die Ruderman-Kittel-Kasuya-Yosida-(RKKY)-WW miteinander, sodass in diesem Material durch die Veränderung eines angelegten Magnetfelds $B$ und der Temperatur $T$ der Zustand von einer AFM-Ordnung, zu einem (paramagnetischen) Schweres-Fermion- (LFL) bzw. Nicht-LFL-Verhalten (NFL) eingestellt werden kann. Unterhalb der Kondo-Temperatur führt eine starke Hybridisierung von $4f$-Elektronen mit Leitungselektronen zu einer deutlichen Verbreiterung der ansonsten atomar-scharfen $4f$-Zustände, sodass die Entwicklung einer schmalen Elektronen-Spin-Resonanz im Kondo-Zustand von \chem{YbRh_2Si_2} sehr überraschend war. Da die bisher veröffentlichten ESR-Messungen vollständig im NFL-Bereich lagen, werden in dieser Arbeit HF-ESR-Daten vorgestellt, die einen tieferen Einblick in die Physik dieser Resonanz erlauben, da sie einen $B-T$-Bereich abdecken, in dem ein Übergang zum LFL-Bereich stattfindet. Die gemessenen $B$- und $T$-Abhängigkeiten der ESR-Parameter im NFL- und im LFL-Bereich weisen darauf hin, dass das Resonanz-Phänomen in \chem{YbRh_2Si_2} als Resonanz schwerer Fermionen betrachtet werden muss. / Strong electronic correlation and the resultant phenomena are object of interest in the modern solid state physics. Such correlation can be found in totally different systems from insulators and semiconductors to metals. This thesis
presents HF-ESR studies of such phenomena in two low dimensional transition metal oxides and two intermetallic compounds.
In ESR the electron spin is used as a local probe to measure the interaction between electrons and the magnetic properties nearby. With increasing electron-electron (EE) interaction the resonance becomes broader, so higher frequencies and higher magnetic fields as usual in commercial available ESR devices are needed to study strong EE interactions. With the used HF-ESR device with a frequency range $\nu=\vu{20-700}{GHz}$ special questions can be investigated where the excitation energies are in the order of $h\nu$ or the resonance effects in high magnetic fields can be explored.
\textbf{CaCu$_2$O$_3$} have the same crystal structure as \chem{SrCu_2O_3}, a textbook example for a 2-leg spin-\textfrac{1}{2}-ladder with a nonmagnetic groundstate and a spin gap separating the excited state. Surprisingly
\chem{CaCu_2O_3} shows an antiferromagnetic (afm) ground state with a relatively high transition temperature. To get a deeper insight in the unexpected afm ordering a combined magnetization and HF-ESR study was performed on a set of
Zn-doped \chem{CaCu_2O_3} samples. Contrary to the Sr-compound in \chem{CaCu_2O_3} the \chem{Cu_2O_3}-ladder-layers are buckled due to a reduced rung angle. Furthermore it is a nonstoichiometric compound \chem{Ca_{1- x} Cu_{2+x}O_{3-
\delta}}, with an excess of Cu in the order of $x\sim 0.16$ which is in the nonmagnetic \chem{Cu^{1+}}-state, sitting close to Ca-sites and a deficiency of oxygen $\delta\sim 0.07$. With this study one can show that (i) in the undoped
compound the extra-spins, responsible for the magnetic Curie-Weiss-behavior, do not sit in the chains, they are sitting on low-symmetry interstitial sites. They recruit themselves from excess \chem{Cu^{1+}}, where the position becomes unstable
close to a O-vacancy so they shift to a interstitial site and become \chem{Cu^{2+}}, (ii) the interstitial site of the extra-spins couple n.n. ladders inside a layer with a direct afm exchange path which lifts the frustration of the spin-ladders so that a afm order with such a high ordering temperature can happen and (iii) the regular interstitial site of the extra-spins explains the weak commensurate spin structure additionally found to the incommensurate spin structure of the ladder-spins in the afm ordered state
The single layered manganate \textbf{LaSrMnO$_4$} is a two dimensional member of the transition metal oxides. In this compound a strong correlation between the orbital and magnetic degree of freedom can be found, so that the afm ordering below $T_N\sim\vu{125}{K}$ comes along with a ferro-orbital ordering of the \chem{Mn^{3+}} $3d$-Orbitals. With HF-ESR we have measured the temperature dependent mixing of the $3d$-orbitals and proved quantitatively the theory of ferro-orbital ordering.
In the afm ordered state below $T_\text{stat}\sim\vu{40}{K}&lt;T_N$ a strong field dependent decrease of the microwave transmission was observed. The frequency dependence of this phenomena could be explained by ferromagnetic polarons
resulting from the interaction of additional charge carriers with the afm ordered spins.
\textbf{GdNi$_2$B$_2$C} The intermetallic borocarbides $R\chem{Ni_2B_2C}$ ($R$ - rare earth metal) attract much attention due to the mutual interaction of superconductivity and afm ordering with complex phase diagrams. One reason for this complexity is the strong magnetic anisotropy coming from the splitting of the $J$-multiplets of the $R$'s $f$-orbitals in
the crystal field. The nonsuperconducting \chem{GdNi_2B_2C} was widely explored because \chem{Gd^{3+}} with a half filled $4f$-shell should show no anisotropic behavior. The HF-ESR study on this system showed, that the assumed pure spin magnet have a uncommonly strong anisotropy which could be ascribed to a highly complex band structure. Involving this new information will help to adjust the model to the reality.
YbRh$_2$Si$_2$ In this heavy fermion system where the magnetic Yb ($4f$) built up a regular Kondo-lattice here is a competition between electron-electron- and the Ruderman-Kittel-Kasuya-Yosida-(RKKY) interaction.
Thats why in this compound a afm ordered state, a (paramagnetic) heavy fermion (LFL) and a non-Fermi-liquid behavior can be established by changing the magnetic field $B$ and/or the temperature $T$. Below the Kondo-temperature $T^*$ a strong hybridization between the conduction electrons and the $4f$-electrons leads to a strong broadening of the otherwise atomic sharp $4f$-states. Thats why the observation of a small electron spin resonance below $T^*$ was very surprising. Because the yet published ESR-measurements are fully in the NFL-state, we performed HF-ESR measurements to study a $B-T$ area where a NFL-LFL crossover appears to get a deeper inside of the physics behind this resonance. The behavior of the measured $T$- and $B$-dependences indicate that this resonance phenomena in \chem{YbRh_2Si_2} is a resonance of heavy fermions.
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On Classical and Quantum Mechanical Energy Spectra of Finite Heisenberg Spin SystemsExler, Matthias 16 May 2006 (has links)
Since the synthesis of Mn12, which can be regarded as the birth of the class of magnetic molecules, many different molecules of various sizes and structures have been produced. The magnetic nature of these molecules originates from a number of paramagnetic ions, whose unpaired electrons form collective angular momenta, referred to as spins. The interaction between these spins can often be described in the Heisenberg model. In this work, we use the rotational band model to predict the energy spectrum of the giant Keplerate {Mo72Fe30}. Based on the approximate energy spectrum, we simulate the cross-section for inelastic neutron scattering, and the results are compared to experimental data. The successful application of our approach substantiates the validity of the rotational band model. Furthermore, magnetic molecules can serve as an example for studying general questions of quantum mechanics. Since chemistry now allows the preparation of magnetic molecules with various spin quantum numbers, this class of materials can be utilized for studying the relations between classical and quantum regime. Due to the correspondence principle, a quantum spin system can be described exactly by classical physics for an infinitely large spin quantum number s. However, the question remains for which quantum numbers s a classical calculation yields a reasonable approximation. Our approach in this work is to develop a converging scheme that adds systematic quantum corrections to the classical density of states for Heisenberg spin systems. To this end, we establish a correspondence of the classical density of states and the quantum spectrum by means of spin-coherent states. The algorithm presented here allows the analysis of how the classical limit is approached, which gives general criteria for the similarity of the classical density of states to the quantum spectrum.
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