161 |
A Pedagogical Investigation of the Development of General Relativity Using Differential FormsSabree, Benjamin David 02 June 2008 (has links)
No description available.
|
162 |
The one place we're trying to get to is just where we can't get: algebraic speciality and gravito-electromagnetism in Bianchi type IXLemberger, Benjamin Kurt 11 June 2014 (has links)
No description available.
|
163 |
PERTURBATIVE METHODS OF SOLUTION FOR BLACK HOLES AND BLACK STRINGS IN BRANEWORLD MODELSSAHABANDU, INOKA C. 05 October 2007 (has links)
No description available.
|
164 |
Application of Methods from Numerical Relativity to Late-Universe CosmologyMertens, James B. 08 February 2017 (has links)
No description available.
|
165 |
An introduction to general relativity and entropy boundsKotze, Jacques 04 1900 (has links)
Thesis (MSc)--University of Stellenbosch, 2006. / ENGLISH ABSTRACT: Entropy bounds arise from Black hole thermodynamics and are a significant departure from the
conventional understanding of the information in a given region. This shift in paradigm is a
consequence of the the fact that there is an unexpected relationship between the area and the
entropy of a given region of spacetime. Entropy bounds are simplified formulations which are
ultimately attempting to be developed into the complete and broad conjecture of the Holographic
Principle. This hasn’t been achieved successfully as yet. In this thesis the aim is to introduce
how the notion of an entropy bound was first suggested and it’s subsequent development into
more robust formulations. The shortcomings of these conjectures are highlighted along with
their strengths.
A foundational introduction of the mathematical requirements for General Relativity is addressed
along with an overview of Einstein’s theory of gravity. This is illustrated by showing
the curvature of relative geodesics as being a consequence of gravity. This is contrasted with
Newtonian theory where gravity is also shown to manifests as the curvature of relative geodesics.
The working background is concluded with a discussion of Einstein’s field equations along with
simple and common solutions often used and required. / AFRIKAANSE OPSOMMING: Swartgat Termodinamika impliseer grense op die entropie, en dus inligting, in ’n gegewe ruimtetyd
volume, wat ’n drastiese afwyking van die tradisionele denkwyse oor inligting impliseer.
Hierdie paradigma skuif het sy oorsprong in ’n onverwagte verband tussen die oppervlakte van,
en entropie bevat, in ’n gegewe ruimte tyd volume. Entropie grense is eenvoudige formulerings
van hierdie verwantskap wat uiteindelik beslag moet kry in die vollediger en wyer holografiese
beginsel. Hierdie doelwit is nog nie bereik nie. Die doel van hierdie tesis is om die oorsprong en
verdere formalisering van entropie grense te verduidelik. Beide die sterk en swak punte van die
formulerings word bespreek.
Algemene relatiwiteits teorie as ’n teorie van gravitasie, sowel as die wiskundige onderbou
daarvan, word oorsigtelik bespreek. Die geometries onderbou van gravitasie word geillustreer
aan die hand van die buiging van relatiewe geodete. Dit word met Newton se gravitasie teorie
vergelyk wat ook in die buiging van relatiewe geodete gemanifesteer word. Hierdie oorsigtelike
agtergrond word afgesluit met ’n oorsig van Einstein se vergelykings, asook eenvoudige en
algemene oplossings wat dikwels nodig is en gebruik word.
|
166 |
Twistor actions for gauge theory and gravityAdamo, Timothy M. January 2012 (has links)
We first consider four-dimensional gauge theory on twistor space, taking as a case study maximally supersymmetric Yang-Mills theory. Using a twistor action functional, we show that gauge theory scattering amplitudes are naturally computed on twistor space in a manner that is much more efficient than traditional space-time Lagrangian techniques at tree-level and beyond. In particular, by rigorously studying the Feynman rules of a gauge-fixed version of the twistor action, we arrive at the MHV formalism. This provides evidence for the naturality of computing scattering amplitudes in twistor space as well as an alternative proof of the MHV formalism itself. Next, we study other gauge theory observables in twistor space including gauge invariant local operators and Wilson loops, and discuss how to compute their expectation values with the twistor action. This enables us to provide proofs for the supersymmetric correlation function / Wilson loop correspondence as well as conjectures on mixed Wilson loop - local operator correlators at the level of the loop integrand. Furthermore, the twistorial formulation of such observables is naturally algebro-geometric; this leads to novel recursion relations for computing mixed correlators by performing BCFW-like deformations of the observables in twistor space. Finally, we apply these twistor actions to gravity. Using the on-shell equivalence between Einstein and conformal gravity in de Sitter space, we argue that the twistor action for conformal gravity should encode the tree-level graviton scattering amplitudes of Einstein's theory. We prove this in terms of generating functionals, and derive the flat space MHV amplitude as well as a recursive version of the MHV amplitude with cosmological constant. We also include some discussion of super-connections and Coulomb branch regularization on twistor space.
|
167 |
Částice se spinem v algebraicky speciálních prostoročasech / Spinning particles in algebraically special space-timesŠrámek, Milan January 2013 (has links)
Spinning-particle motion is studied, within the pole-dipole approximation, in algebraically special space-times of type N, III and D. The spin-curvature interaction is analysed for the Pirani and Tulczyjew spin supplementary conditions; for N and D types, the condition is related to a relative acceleration of two near observers separated in the direction of particle's spin. For Tulczyjew's condition, the momentum-velocity relation is also studied as well as its consequences for the spin-curvature interaction. Finally, the type of motion is mentioned for which both the supplementary conditions considered are equivalent.
|
168 |
Numerical simulations of instabilities in general relativityKunesch, Markus January 2018 (has links)
General relativity, one of the pillars of our understanding of the universe, has been a remarkably successful theory. It has stood the test of time for more than 100 years and has passed all experimental tests so far. Most recently, the LIGO collaboration made the first-ever direct detection of gravitational waves, confirming a long-standing prediction of general relativity. Despite this, several fundamental mathematical questions remain unanswered, many of which relate to the global existence and the stability of solutions to Einstein's equations. This thesis presents our efforts to use numerical relativity to investigate some of these questions. We present a complete picture of the end points of black ring instabilities in five dimensions. Fat rings collapse to Myers-Perry black holes. For intermediate rings, we discover a previously unknown instability that stretches the ring without changing its thickness and causes it to collapse to a Myers-Perry black hole. Most importantly, however, we find that for very thin rings, the Gregory-Laflamme instability dominates and causes the ring to break. This provides the first concrete evidence that in higher dimensions, the weak cosmic censorship conjecture may be violated even in asymptotically flat spacetimes. For Myers-Perry black holes, we investigate instabilities in five and six dimensions. In six dimensions, we demonstrate that both axisymmetric and non-axisymmetric instabilities can cause the black hole to pinch off, and we study the approach to the naked singularity in detail. Another question that has attracted intense interest recently is the instability of anti-de Sitter space. In this thesis, we explore how breaking spherical symmetry in gravitational collapse in anti-de Sitter space affects black hole formation. These findings were made possible by our new open source general relativity code, GRChombo, whose adaptive mesh capabilities allow accurate simulations of phenomena in which new length scales are produced dynamically. In this thesis, we describe GRChombo in detail, and analyse its performance on the latest supercomputers. Furthermore, we outline numerical advances that were necessary for simulating higher dimensional black holes stably and efficiently.
|
169 |
Černé díry pod vlivem silných zdrojů gravitace / Black holes under the influence of strong sources of gravitationKotlařík, Petr January 2019 (has links)
In this thesis we study a deformation of a black-hole spacetime due to another strong sources of gravity. Keeping within static and axially symmetric metrics, we consider a binary of Schwarzschild black holes held apart from each other by a repulsive effect of an Appell ring. After verifying that such a system can rest in static equilibrium (without any supporting struts), we compute its several basic geometric characteristics and we plot simple invariants determined by the metric functions (especially lapse, or, equivalently, potential) and by their first and second derivatives (gravitational acceleration and Kretschmann scalar). Then we extend the analysis below the black-hole horizon and inspect the behaviour of the scalars inside. The geometry turns out to be deformed in a non-trivial way, we even find regions of negative Kretschmann scalar in some cases. In the second part, we present a summary of the perturbative solution describing a slowly rotating system of a black hole surrounded by a thin finite circular disc, and an analysis of equatorial circular geodesics in such a spacetime. 1
|
170 |
Cosmological Models and Singularities in General RelativitySandin, Patrik January 2011 (has links)
This is a thesis on general relativity. It analyzes dynamical properties of Einstein's field equations in cosmology and in the vicinity of spacetime singularities in a number of different situations. Different techniques are used depending on the particular problem under study; dynamical systems methods are applied to cosmological models with spatial homogeneity; Hamiltonian methods are used in connection with dynamical systems to find global monotone quantities determining the asymptotic states; Fuchsian methods are used to quantify the structure of singularities in spacetimes without symmetries. All these separate methods of analysis provide insights about different facets of the structure of the equations, while at the same time they show the relationships between those facets when the different methods are used to analyze overlapping areas. The thesis consists of two parts. Part I reviews the areas of mathematics and cosmology necessary to understand the material in part II, which consists of five papers. The first two of those papers uses dynamical systems methods to analyze the simplest possible homogeneous model with two tilted perfect fluids with a linear equation of state. The third paper investigates the past asymptotic dynamics of barotropic multi-fluid models that approach a `silent and local' space-like singularity to the past. The fourth paper uses Hamiltonian methods to derive new monotone functions for the tilted Bianchi type II model that can be used to completely characterize the future asymptotic states globally. The last paper proves that there exists a full set of solutions to Einstein's field equations coupled to an ultra-stiff perfect fluid that has an initial singularity that is very much like the singularity in Friedman models in a precisely defined way. / <p>Status of the paper "Perfect Fluids and Generic Spacelike Singularities" has changed from manuscript to published since the thesis defense.</p>
|
Page generated in 0.0873 seconds