Thermalization and Out-of-Equilibrium Dynamics in Open Quantum Many-Body Systems

Buchhold, Michael

23 September 2015

Thermalization, the evolution of an interacting many-body system towards a thermal Gibbs ensemble after initialization in an arbitrary non-equilibrium state, is currently a phenomenon of great interest, both in theory and experiment. As the time evolution of a quantum system is unitary, the proposed mechanism of thermalization in quantum many-body systems corresponds to the so-called eigenstate thermalization hypothesis (ETH) and the typicality of eigenstates. Although this formally solves the contradiction of thermalizing but unitary dynamics in a closed quantum many-body system, it does neither make any statement on the dynamical process of thermalization itself nor in which way the coupling of the system to an environment can hinder or modify the relaxation dynamics. In this thesis, we address both the question whether or not a quantum system driven away from equilibrium is able to relax to a thermal state, which fulfills detailed balance, and if one can identify universal behavior in the non-equilibrium relaxation dynamics. As a first realization of driven quantum systems out of equilibrium, we investigate a system of Ising spins, interacting with the quantized radiation field in an optical cavity. For multiple cavity modes, this system forms a highly entangled and frustrated state with infinite correlation times, known as a quantum spin glass. In the presence of drive and dissipation, introduced by coupling the intra-cavity radiation field to the photon vacuum outside the cavity via lossy mirrors, the quantum glass state is modified in a universal manner. For frequencies below the photon loss rate, the dissipation takes over and the system shows the universal behavior of a dissipative spin glass, with a characteristic spectral density $\\mathcal{A}(\\omega)\\sim\\sqrt{\\omega}$. On the other hand, for frequencies above the loss rate, the system retains the universal behavior of a zero temperature, quantum spin glass. Remarkably, at the glass transition, the two subsystems of spins and photons thermalize to a joint effective temperature, even in the presence of photon loss. This thermalization is a consequence of the strong spin-photon interactions, which favor detailed balance in the system and detain photons from escaping the cavity. In the thermalized system, the features of the spin glass are mirrored onto the photon degrees of freedom, leading to an emergent photon glass phase. Exploiting the inherent photon loss of the cavity, we make predictions of possible measurements on the escaping photons, which contain detailed information of the state inside the cavity and allow for a precise, non-destructive measurement of the glass state. As a further set of non-equilibrium systems, we consider one-dimensional quantum fluids driven out of equilibrium, whose universal low energy theory is formed by the so-called Luttinger Liquid description, which, due to its large degree of universality, is of intense theoretical and experimental interest. A set of recent experiments in research groups in Vienna, Innsbruck and Munich have probed the non-equilibrium time-evolution of one-dimensional quantum fluids for different experimental realizations and are pushing into a time regime, where thermalization is expected. From a theoretical point of view, one-dimensional quantum fluids are particular interesting, as Luttinger Liquids are integrable and therefore, due to an infinite number of constants of motion, do not thermalize. The leading order correction to the quadratic theory is irrelevant in the sense of the renormalization group and does therefore not modify static correlation functions, however, it breaks integrability and will therefore, even if irrelevant, induce a completely different non-equilibrium dynamics as the quadratic Luttinger theory alone. In this thesis, we derive for the first time a kinetic equation for interacting Luttinger Liquids, which describes the time evolution of the excitation densities for arbitrary initial states. The resonant character of the interaction makes a straightforward derivation of the kinetic equation, using Fermi\'s golden rule, impossible and we have to develop non-perturbative techniques in the Keldysh framework. We derive a closed expression for the time evolution of the excitation densities in terms of self-energies and vertex corrections. Close to equilibrium, the kinetic equation describes the exponential decay of excitations, with a decay rate $\\sigma^R=\\mbox\\Sigma^R$, determined by the self-energy at equilibrium. However, for long times $\\tau$, it also reveals the presence of dynamical slow modes, which are the consequence of exactly energy conserving dynamics and lead to an algebraic decay $\\sim\\tau^$ with $\\eta_D=0.58$. The presence of these dynamical slow modes is not contained in the equilibrium Matsubara formalism, while they emerge naturally in the non-equilibrium formalism developed in this thesis. In order to initialize a one-dimensional quantum fluid out of equilibrium, we consider an interaction quench in a model of interacting, dispersive fermions in Chap.~\\ref. In this scenario, the fermionic interaction is suddenly changed at time $t=0$, such that for $t>0$ the system is not in an eigenstate and therefore undergoes a non-trivial time evolution. For the quadratic theory, the stationary state in the limit $t\\rightarrow\\infty$ is a non-thermal, or prethermal, state, described by a generalized Gibbs ensemble (GGE). The GGE takes into account for the conservation of all integrals of motion, formed by the eigenmodes of the Hamiltonian. On the other hand, in the presence of non-linearities, the final state for $t\\rightarrow\\infty$ is a thermal state with a finite temperature $T>0$. . The spatio-temporal, dynamical thermalization process can be decomposed into three regimes: A prequench regime on the largest distances, which is determined by the initial state, a prethermal plateau for intermediate distances, which is determined by the metastable fixed point of the quadratic theory and a thermal region on the shortest distances. The latter spreads sub-ballistically $\\sim t^$ in space with $0<\\alpha<1$ depending on the quench. Until complete thermalization (i.e. for times $t<\\infty$), the thermal region contains more energy than the prethermal and prequench region, which is expressed in a larger temperature $T_{t}>T_$, decreasing towards its final value $T_$. As the system has achieved local detailed balance in the thermalized region, energy transport to the non-thermal region can only be performed by the macroscopic dynamical slow modes and the decay of the temperature $T_{t}-T_\\sim t^$ again witnesses the presence of these slow modes. The very slow spreading of thermalization is consistent with recent experiments performed in Vienna, which observe a metastable, prethermal state after a quench and only observe the onset of thermalization on much larger time scales. As an immediate indication of thermalization, we determine the time evolution of the fermionic momentum distribution after a quench from non-interacting to interacting fermions. For this quench scenario, the step in the Fermi distribution at the Fermi momentum $k\\sub$ decays to zero algebraically in the absence of a non-linearity but as a stretched exponential (the exponent being proportional to the non-linearity) in the presence of a finite non-linearity. This can serve as a proof for the presence or absence of the non-linearity even on time-scales for which thermalization can not yet be observed. Finally, we consider a bosonic quantum fluid, which is driven away from equilibrium by permanent heating. The origin of the heating is atomic spontaneous emission of laser photons, which are used to create a coherent lattice potential in optical lattice experiments. This process preserves the system\'s $U(1)$-invariance, i.e. conserves the global particle number, and the corresponding long-wavelength description is a heated, interacting Luttinger Liquid, for which phonon modes are continuously populated with a momentum dependent rate $\\partial_tn_q\\sim\\gamma |q|$. In the dynamics, we identify a quasi-thermal regime for large momenta, featuring an increasing time-dependent effective temperature. In this regime, due to fast phonon-phonon scattering, detailed balance has been achieved and is expressed by a time-local, increasing temperature. The thermal region emerges locally and spreads in space sub-ballistically according to $x_t\\sim t^{4/5}$. For larger distances, the system is described by an non-equilibrium phonon distribution $n_q\\sim |q|$, which leads to a new, non-equilibrium behavior of large distance observables. For instance, the phonon decay rate scales universally as $\\gamma_q\\sim |q|^{5/3}$, with a new non-equilibrium exponent $\\eta=5/3$, which differs from equilibrium. This new, universal behavior is guaranteed by the $U(1)$ invariant dynamics of the system and is insensitive to further subleading perturbations. The non-equilibrium long-distance behavior can be determined experimentally by measuring the static and dynamic structure factor, both of which clearly indicate the exponents for phonon decay, $\\eta=5/3$ and for the spreading of thermalization $\\eta_T=4/5$. Remarkably, even in the presence of this strong external drive, the interactions and their aim to achieve detailed balance are strong enough to establish a locally emerging and spatially spreading thermal region. The physical setups in this thesis do not only reveal interesting and new dynamical features in the out-of-equilibrium time evolution of interacting systems, but they also strongly underline the high degree of universality of thermalization for the classes of models studied here. May it be a system of coupled spins and photons, where the photons are pulled away from a thermal state by Markovian photon decay caused by a leaky cavity, a one-dimensional fermionic quantum fluid, which has been initialized in an out-of-equilibrium state by a quantum quench or a one-dimensional bosonic quantum fluid, which is driven away from equilibrium by continuous, external heating, all of these systems at the end establish a local thermal equilibrium, which spreads in space and leads to global thermalization for $t\\rightarrow\\infty$. This underpins the importance of thermalizing collisions and endorses the standard approach of equilibrium statistical mechanics, describing a physical system in its steady state by a thermal Gibbs ensemble.

info:eu-repo/classification/ddc/530

ddc:530

Etude théorique des fluctuations de courant, de l'admittance et de la densité d'états d'un nano système en interaction / Theoretical study of current correlations, admittance and density of states of an interacting nano-system.

Zamoum, Redouane

27 September 2013

Dans cette thèse nous avons étudié les fluctuations de courant, l'admittance quantique ainsi que la densité d'états pour un nano système en interaction. Dans la première partie de la thèse, nous avons étudié les fluctuations de courant et l'admittance pour un conducteur unidimensionnel, en décrivant le système par un liquide de Tomonaga-Luttinger. Les techniques de bosonisation et de refermionisation permettent d'avoir des résultats exacts. Ces résultats sont appliqués à un conducteur cohérent couplé à un quantum de résistance, et aux états de bord dans le régime de l'effet Hall quantique fractionnaire. Dans le cas d'un conducteur cohérent, le bruit non symétrisé à fréquence finie exhibe un profil différent de celui de la théorie de la diffusion, et la conductance à fréquence finie est directement liée au courant. Dans le cas des états de bord, nous avons établi une relation entre les corrélations de courant et l'admittance dans certaines limites. En particulier, les singularités qui apparaissent dans les corrélations de courant sont celles de l'admittance. Dans la deuxième partie, nous avons étudié un fil quantique connecté à deux réservoirs représentés par deux impuretés. Le système est décrit par un liquide de Tomonaga-Luttinger. Nous avons établi et résolu l'équation de Dyson pour la fonction de Green retardée. Ce qui permet de calculer la densité d'états pour un fil quantique homogène puis inhomogène. Dans le cas d'un paramètre d'interaction homogène, l'effet des impuretés modifie le profil de la densité d'états. Dans le cas d'un paramètre d'interaction inhomogène, le calcul de la densité d'états est plus difficile et une approche numérique est indispensable. / In this thesis we focus on the study of the current fluctuations, quantum admittance and density of states of an interacting nano system. The first part of the thesis is related to the calculation of current fluctuations and admittance for one dimensional conductor. The system is described by a Tomonaga-Luttinger liquid. The use of bosonization and refermionization procedures allows us to obtain exact results, valuable whatever the value of the applied voltage, for all frequencies and all temperature regimes. Tow cases are studied. In the first one, we consider a coherent conductor coupled to a quantum of resistance. We find that the finite frequency noise behavior differs from that of the scattering theory, and the finite frequency conductance is directly related to the current. In the second case, we study edge states in the fractional quantum Hall regime. We establish a relationship between the current correlations and the admittance in certain limits. Thus, the singularities observed in the current correlations are those of the admittance. The second part of the thesis is devoted to the study of an interacting quantum wire connected to tow leads modeled as two impurities. The system is described by a Tomonaga-Luttinger liquid. We derived and solved an exact Dyson equation for a retarded Green function. Than we calculate the density of states in two cases, homogeneous quantum wire, and next inhomogeneous one. The effect of the impurities changes the behavior of the density of states for the homogeneous case. In the case of a position depending interaction parameter, the calculation of the density of states is more difficult and a numerical approach is needed.

Transport quantique

Liquide de Tomonaga-Luttinger

Bosonisation

Refermionisation

Effet Hall quantique fractionnaire

Conducteur cohérent

Mapping

Fil quantique

Équation de Dyson

Fonction de Green retardée

Quantum transpor

Tomonaga-Luttinger liquid

Bosonization

Refermionisation

Fractional quantum Hall effect

Coherent conductor

Mapping

Quantum wire

Dyson equation

Retarded Green function

539

Supraconductivité non conventionnelle et impuretés locales dans les semi-métaux de Luttinger

Godbout, Louis

12 1900

Ce mémoire présente les résultats sur l’étude de la supraconductivité et de la réponse à des impuretés locales électrique et magnétiques des semi-métaux de Luttinger. Ces semi-métaux correspondent à des matériaux tri-dimensionnels dont la relation de dispersion électronique est caractérisée par des bandes quadratiques qui se touchent, en présence d’un fort couplage spin-orbite caractérisé par une pseudo-spin-3/2. Expérimentalement, certains semi-métaux de Luttinger supraconducteurs possèdent une température critique ne pouvant être expliquée par les théories conventionnelles (BCS) se référant principalement au mécanisme des phonons. Le volet supraconductivité de notre travail s’intéresse à la résolution numérique de l’équation d’Eliashberg, une théorie microscopique de la supraconductivité, avec interactions Coulombiennes écrantées comme mécanisme d’appariement des paires de Cooper. Nos résultats concernant la température critique montrent une dépendance linéaire avec la température de Fermi du matériau et nous constatons un accord entre température critique expérimentale et de notre modèle pour divers semi-métaux de Luttinger à base de bismuth, comme YPtBi, YPdBi, LuPtBi et LuPdBi. La réponse en densité de charge et spin à des impuretés locales électriques et magnétiques est aussi étudiée à température nulle analytiquement et à température non-nulle numériquement et est comparée aux résultats connus du gaz d’électron libre et des semi-métaux de Dirac. Contrairement à ces dernier, une réponse magnétique anisotropique est observée pour les semi-métaux de Luttinger et la susceptibilité magnétique de spin résultante se trouve être diamagnétique. Un Hamiltonien d’interaction entre deux impuretés magnétiques médié par le mécanisme RKKY, l’interaction entre des impuretés magnétiques obtenue par l’intermédiaire des électrons libres du matériau, est aussi présenté et discuté pour différents semi-métaux. Cette interaction par couplage RKKY pourrait être à l’origine de phases magnétiques exotiques, comme dans le cas du pyrochlore Pr2Ir2O7. Nous terminons en soulignant les explorations possibles concernant nos résultats, en ajoutant ou modifiant des termes brisant une symétrie dans l’Hamiltonien initial. / In this master thesis, I review my work on the superconductivity and on the inhomogeneities induced by impurities in Luttinger semimetals. Luttinger semimetals are characterized by a quadratic band-touching between electron and hole bands, at a time-reversal-invariant point of the Brillouin zone, and that describes effectively pseudo-spin 3/2 fermions. The superconductivity in some Luttinger semimetals can be peculiar due to the increase of the optical dielectric constant through interband excitations. For example, in YPtBi, the superconducting critical temperature is at odds with theoretical expectations from the BCS theory where Cooper pairs are induced by lattice vibrations, the phonons. We thus explore another mechanism of superconductivity, through the microscopic theory of Eliashberg that we solve numerically and where Cooper pairs are induced by the screened Coulomb interaction. In particular we compute the critical temperature and show that it scales linearly with the Fermi temperature of electrons, and compare our results to experimental observations. The multiple bands in Luttinger semimetals also affect the inhomogeneities in charge and in spin due to a charged or a magnetic impurity. We mainly study this phenomenon at zero temperature through analytical calculations and explore the influence of temperature numerically. We compare our results with inhomogeneities in a normal and in a Dirac electron gas. In particular, our results indicate that Luttinger semimetals tend to be diamagnetic on the contrary to normal and Dirac electron gases. We also derive the effective Hamiltonian of two magnetic impurities, where their mutual interaction is mediated by conduction electrons, also known as the RKKY mechanism. This interaction by RKKY coupling could be at the origin of exotic magnetic phases, as in the case of the pyrochlore Pr2Ir2O7. We finish by highlighting possible explorations of our results, by adding or modifying terms in the initial Hamiltonian.

semi-métaux de Luttinger

couplage spin-orbite

supraconductivité non-conventionnelle

équation d’Eliashberg

potentiel Coulombien écranté

interaction RKKY

susceptibilité de spin

Luttinger semimetals

spin-orbit coupling

unconventional superconductivity

Eliashberg equation

screened Coulomb potential

RKKY interaction

spin susceptibility

Étude des transitions de Peierls dans les systèmes unidimensionnels et quasi-unidimensionnels

Bakrim, Hassan

January 2010

We studied the structural instabilities of one-dimensional (1D) and quasi-one-dimensional (Q1D) electron-phonon systems at low temperature through two models, SuSchrieffer-Heeger (SSH) and molecular crystal (CM) with and without spin. The phase diagrams are obtained using a Kadanoff-Wilson renormalization group approach (GR). For the 1D half-filled system the study of the frequency dependence of the electronic gap allowed us to connect continuously the two limits, adiabatic and non-adiabatic. The Peierls and Cooper channels interference and the quantum fluctuations reduce the gap. A regime change occurs when the frequency becomes of the order of mean field gap, marking a quantum-classical crossover that is the Kosterlitz-Thouless type. At this level, the effective coupling behaves in power law function on frequency. For the case with spin, a gapped Peierls state is maintained in the non-adiabatic limit, while for the case without spin, the system transits to ungapped disordered state, namely the Luttinger liquid stat (LL). For the SSH model without spin, the GR confirms the existence of a threshold phonon coupling beyond which the gap is restored. The study of the rigidities of the two models without spin allowed us to trace the main features of the LL state predicted by the bosonization method. The study of the Holstein-Hubbard model has allowed us not only to reproduce the phase diagrams already obtained by the Monte Carlo method, but to highlight two additional phases, namely, free fermions phase and the bond charge-density-wave phase. We have extended this study to the quarter-filled Q1D Peierls systems at finite temperature. Within the SSH model, an unconventional superconducting phase with spin singlet symmetry SS-s emerges at low temperature when the deviation to the perfect nesting of the Fermi surface is strong enough. Peierls-SS transition is characterized by the presence of a quantum critical point at low frequency and by a power law behavior of the transition temperature as a function of frequency with an exponent identical to one of 1D system. This exponent which universality has been verified contrasts with the BCS result. Coulomb interactions have been introduced through the study of the extended SSH-Hubbard model. The extension of this work to half-filled SSH and CM cases was also performed.

Quantum critical point

Kosterlitz-Thouless transition

Quantum-classical crossover

Unconventional superconductivity

Luttinger liquid

Peierls stat

Stiffness factor

Holstein-Hubbard

Molecular crystal

Su-Schrieffer-Heeger

Kadanoff-Wilson renormalization group

Theoretical studies of underscreened Kondo physics in quantum dots

Wright, Christopher James

January 2011

We study correlated two-level quantum impurity models coupled to a metallic conduction band in the hope of gaining insight into the physics of nanoscale quantum dot systems. We focus on the possibility of formation of a spin-1 impurity local moment which, on coupling to the band, generates an underscreened (USC) singular Fermi liquid state. By employing physical arguments and the numerical renormalization group (NRG) technique, we analyse such systems in detail examining in particular both the thermodynamic and dynamic properties, including the differential conductance. The quantum phase transitions occurring between the USC phase and a more ordinary Fermi liquid (FL) phase are analysed in detail. They are generically found to be of Kosterlitz-Thouless type; exceptions occur along lines of high symmetry where first-order transitions are found. A `Friedel-Luttinger sum rule' is derived and, together with a generalization of Luttinger's theorem to the USC phase, is used to obtain general results for the $T=0$ zero-bias conductance --- it is expressed solely in terms of the number of electrons present on the impurity and applicable in both the USC and FL phases. Relatedly, dynamical signatures of the quantum phase transition show two broad classes of behaviour corresponding to the collapse of either a resonance or antiresonance in the single-particle density of states. Evidence of both of these behaviours is seen in experimental devices. We study also the effect of a local magnetic field on both single- and two-level quantum impurities. In the former case we attempt to resolve some points of contention that remain in the literature. Specifically we show that the position of the maximum in the spin resolved density of states (and related peaks in the differential conductance) is not linear in the applied field, showing a more complicated form than a simple `Zeeman splitting'. The analytic result for the low-field asymptote is recovered. For two-level impurities we illustrate the manner in which the USC state is destroyed: due to two cancelling effects an abrupt change in the zero-bias conductance does not occur as one might expect. Comparison with experiment is made in both cases and used to interpret experimental findings in a manner contrary to previous suggestions. We find that experiments are very rarely in the limit of strong impurity-host coupling. Further, features in the differential conductance as a function of bias voltage should not be simply interpreted in terms of isolated quantum dot states. The many-body nature of such systems is crucially important to their observed properties.

621.38152

Zeemanův jev v polovodičových kvantových strukturách / Zeemanův jev v polovodičových kvantových strukturách

Stráský, Josef

January 2011

This theoretical thesis presents detailed study of negatively charged excitons - trions - confined in single quantum well in presence of perpendicular magnetic field. Complex valence band of GaAs/GaAlAs compound is described within Luttinger Hamiltonian framework. Singlet and triplet states of negative trion are introduced. Advanced theoretical analysis of Zeeman effect for different states of trion is performed. Landau gauge of magnetic field and unusual wavefunctions basis is chosen and its accuracy is tested. Evolution of ground state energy and photoluminescence spectra with magnetic field is evaluated for different values of Landé g-factors. Probability of occurrence of electrons with respect to the hole position and their spatial correlation function are investigated.

Novel properties of interacting particles in small low-dimensional systems.

Romanovsky, Igor Alexandrovich

11 July 2006

This work is about the properties of several low dimensional, small systems of interacting particles. We demonstrate that interaction between particles in the low dimensional small systems can lead to many unexpected effects. We considered electrons in a Luttinger liquid, in a superconducting state, and atoms in a magneto-optical trap. Using bosonization techniques we calculated the thermopower of a Luttinger liquid wire with an impurity. We predicted the appearance of a phase dependent force and resonant phase dependent magnetization in the nanoscopic superconductor - normal metal superconductor (or superconductor - two dimensional electron gas - superconductor) junction. We also considered plasma oscillations inside thin superconducting tubes and rings and predicted that the velocities of the plasmons in these systems are periodic functions of the magnetic flux. By considering neutral atoms in a harmonic trap we discovered that strongly repelling atoms do not form Bose-Einstein condensate at zero temperature but tend to occupy different orbitals with small mutual overlap, forming crystallite structures similar to Wigner molecules of electrons inside a quantum dot.

Plasma oscillations in superconductors

Trapped bosons

Luttinger liquid

Thermopower

S/N/S junctions

Aharonov-Bohm effect

Low-dimensional systems

Strongly correlated particles

Quantum theory

Electron transport

Low-dimensional semiconductors

Plasma oscillations

Nonlinear Optical Effects in Pure and N-Doped Semiconductors

Donlagic, Nias Sven

02 November 2000

No description available.

530 Physik

Mathematics and Computer Science

quantum kinetic equations

phonons

excitons

Fermi-edge singularity

Tomonaga-Luttinger model

four-wave-mixing

33.10

RVQ 000: Halbleiter {Physik}

Magnétisme Quantique, Bosons en interaction et basse dimensionnalité

Orignac, Edmond

20 February 2013

Les systèmes de spin antiferromagnétiques en une dimension présentent des caractéristiques remarquables. Le théorème de Mermin-Wagner montre que même dans l'état fondamental de leur Hamiltonien, ces systèmes ne possèdent pas d'ordre à longue distance dans leurs fonctions de corrélation spin-spin s'ils possèdent une symétrie continue. Néanmoins, un quasi-ordre à longue distance peut exister, avec des fonctions de corrélation spin-spin décroissant en loi de puissance avec la distance, comme par exemple dans la chaîne de spin-1/2. Ce cas est décrit par la théorie des liquides de Luttinger. Même dans le cas d'un ordre à courte distance où les fonctions de corrélations spin-spin décroissent exponentiellement, un ordre topologique peut être présent. Il peut être mis en évidence par un paramètre d'ordre dépendant des opérateurs de spin de façon non-locale ou par la présence d'excitations de bord, comme par exemple dans le cas de la chaînes de spin-1. D'autre part, il existe une équivalence formelle entre les opérateurs de spin-1/2 et les bosons de coeur dur, qui permet de traduire les propriétés des systèmes magnétiques dans le langage des bosons en interaction. Après une rapide revue des méthodes théoriques utilisées pour la description des systèmes de basse dimensionnalité, je décrirais mes travaux sur les systèmes échelles de spin antiferromagnétiques et les applications aux systèmes de bosons en interaction.

Liquides de Luttinger

gap de Haldane

échelles de spin

modèle d'Aubry-André

Magnetické anizotropie v (Ga,Mn)As a v kovových multivrstvách se silnou spin-orbitální interakcí / Magnetic anisotropies in (Ga,Mn)As and metallic multilayers with strong spin-orbit coupling

Zemen, Jan

January 2010

The thesis presents a numerical study of magnetocrystalline anisotropies in dilute ferromagnetic semiconductors and transition metal systems intended to advance the current understanding of the microscopic origins of this relativistic effect and to contribute to the development of spintronic devices with new functionalities. The major part of the work surveys magnetocrystalline anisotropies in (Ga,Mn)As epilayers and compares the calculations to available experimental data. Our model is based on an envelope function description of the valence band holes and a spin representation for their kinetic-exchange interaction with localised electrons on Mn2+ ions, treated in the mean-field approximation. For epilayers with growth induced lattice-matching strains we study in-plane to out-of-plane easy axis reorientations as a function of Mn local-moment concentration, hole concentration, and temperature. Next we focus on the competition of in-plane cubic and uniaxial anisotropies. We add an in-plane shear strain to the effective Hamiltonian in order to capture measured data in bare, unpatterned epilayers, and we provide microscopic justification for this approach. The model is then extended by an in-plane uniaxial strain and used to directly describe experiments with magnetisation direction controlled by...