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Gravitational collapse of orogenic belts a preliminary study /Shen, Yunqing. January 1997 (has links)
Thesis (Ph. D.)--University of Missouri-Columbia, 1997. / Typescript. Vita. Includes bibliographical references (leaves 168-186). Also available on the Internet.
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Late-time particle creation from gravitational collapse to an extremal Reissner-Nordstrom black hole /Gao, Sijie. January 2002 (has links)
Thesis (Ph. D.)--University of Chicago, Dept. of Physics, August 2002. / Includes bibliographical references (p. 31). Also available on the Internet.
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Black Spaghetti: A Numerical Model of Gravitational Collapse in 4 + 1 SpacetimeChristenson, Michael P. 08 July 2005 (has links) (PDF)
We investigate spherically-symmetric gravitational collapse in the presence of a single "large" extra dimension through the use of analytical and numerical techniques. This has bearing on higher-dimensional ideas concerning hypothetical objects called "black strings," or black holes extending into an extra circular dimension, which dimension we hereinafter label zeta. These putative objects were first seriously considered as elements of string theory but have relevance in simpler, higher-dimensional generalization of Einstein's general relativity. We assume a universe topologically consisting of a two-dimensional Lorentzian manifold crossed with the sphere, crossed again with the circle. We model the formation of a uniform black string via two modes—the collapse of a massless scalar field, and of pure gravitational waves consisting of (gaussian) distortions in the extra dimension. We report on and discuss two aspects of the nonlinear dynamics, viz., that in five dimensions larger-amplitude fields appear to collapse more slowly than their lower amplitude cousins; and that pure gravitational field collapse exhibits signs of self-similarity at the threshold between black string formation and dispersal of the collapsing field.
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Radiating solutions with heat flow in general relativity.Govender, Megandren. January 1994 (has links)
In this thesis we model spherically symmetric radiating stars dissipating energy in
the form of a radial heat flux. We assume that the spacetime for the interior matter
distribution is shear-free. The junction conditions necessary for the matching of the
exterior Vaidya solution to an interior radiating line element are obtained. In particular
we show that the pressure at the boundary of the star is nonvanishing when the
star is radiating (Santos 1985). The junction conditions, with a nonvanishing cosmological
constant, were obtained. This generalises the results of Santos (1985) and we
believe that this is an original result. The Kramer (1992) model is reviewed in detail
and extended. The evolution of this model depends on a function of time which has
to satisfy a nonlinear second order differential equation. We solve this differential
equation in general and thereby completely describe the temporal behaviour of the
Kramer model. Graphical representations of the thermodynamical and gravitational
variables are generated with the aid of the software package MATHEMATICA Version
2.0 (Wolfram 1991). We also analyse two other techniques to generate exact
solutions to the Einstein field equations for modelling radiating stars. In the first
case the particle trajectories are assumed to be geodesics. We indicate how the model
of Kolassis et al (1988) may be extended by providing an ansatz to solve a second
order differential equation. In the second case we review the models of de Oliveira
et al (1985, 1986, 1988) where the gravitational potentials are separable functions of
the spatial and temporal coordinates. / Thesis (M.Sc.)-University of Natal, 1994.
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Taking magnetic resonance into industrial applicationsBlythe, Thomas January 2018 (has links)
Magnetic resonance (MR) is a highly versatile technique with great potential for use in industrial applications; from the in situ study of unit operations to the optimisation of product properties. This thesis, concerned with the latter, is divided into two parts. Firstly, dynamic MR is applied to characterise the flow behaviour, or rheology, of process fluids. Such characterisation is typically performed using conventional rheometry methods operating offline, with an online, or inline, method sought for process control and optimisation. Until recently, MR was an unlikely choice for this application due to the requirement of high-field MR hardware. However, recent developments in low-field MR hardware mean that the potential of MR in such applications can now be realised. Since the implementation of MR flow imaging is challenging on low-field MR hardware, two new approaches to MR rheometry are described using pulsed field gradient (PFG) MR. A cumulant analysis of the PFG MR signal is first used to characterise the rheology of model power-law fluids, namely xanthan gum-in-water solutions, accurate to within 5% of conventional rheometry, the data being acquired in only 6% of the time required when using MR flow imaging. The second approach utilises a Bayesian analysis of the PFG MR signal to characterise the rheology of model Herschel--Bulkley fluids, namely Carbopol 940-in-water solutions; data are acquired in only 12% of the time required for analysis using MR flow imaging. The suitability of the Bayesian MR approach to study process fluids is demonstrated through experimental study on an alumina-in-acetic acid slurry used by Johnson Matthey. Secondly, MR imaging is used to provide insights into the origins and mechanisms of colloidal gel collapse. Many industrial products are colloidal gels, a space-spanning network of attractive particles with a yield stress. Colloidal gels are, however, known to undergo gravitational collapse after a latency period, thus limiting the shelf-life of products. This remains poorly understood, with a more detailed understanding of both fundamental interest and practical importance. To this end, MR imaging is applied offline to investigate the phase behaviour of colloidal gels. In particular, a comparison of the simulated and experimental phase diagrams suggests gravitational gel collapse to be gravity-driven. Furthermore, measurement of the colloid volume fraction using MR imaging indicates the formation of clusters of colloids at the top of the samples. Whether such clusters initiate gravitational gel collapse is yield stress-dependent; the gravitational stress exerted by a cluster must be sufficient to yield the colloidal gel.
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Black Hole Formation, Explosion and Gravitational Wave Emission from Rapidly Rotating Very Massive Stars / 高速回転する非常に重い星のブラックホール形成、爆発及び重力波放出についての研究Uchida, Haruki 25 March 2019 (has links)
京都大学 / 0048 / 新制・課程博士 / 博士(理学) / 甲第21557号 / 理博第4464号 / 新制||理||1641(附属図書館) / 京都大学大学院理学研究科物理学・宇宙物理学専攻 / (主査)教授 柴田 大, 教授 田中 貴浩, 教授 井岡 邦仁 / 学位規則第4条第1項該当 / Doctor of Science / Kyoto University / DGAM
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Phenomenology and Astrophysics of Gravitationally-Bound Condensates of Axion-Like ParticlesEby, Joshua 30 October 2017 (has links)
No description available.
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Efeitos de um vácuo dinâmico na evolução cósmica e no colapso gravitacional / Running vacuum effects in cosmic evolution and gravitational collapsePerico, Eder Leonardo Duarte 12 March 2015 (has links)
As observações astronômicas dos últimos 15 anos revelaram que o universo atualmente está expandindo aceleradamente. No contexto da relatividade geral se acredita que a energia escura, cujo melhor candidato é a densidade do vácuo ($\\Lambda/8\\pi G$), é o agente responsável por este estado acelerado. No entanto, o termo $\\Lambda$ tem duas sérias dificuldades: o problema da constante cosmológica e o problema da coincidência. Com o objetivo de aliviar o problema da constante cosmológica, muitos modelos adotam um termo $\\Lambda$ dinâmico, permitindo seu decrescimento ao longo de toda a história cósmica. Neste tipo de modelo, a equação de conservação do tensor momento energia total exige uma troca de energia entre a densidade do vácuo e as outras componentes energéticas do universo; o que também alivia o problema da coincidência. Neste trabalho discutimos diferentes consequências de um vácuo dinâmico no âmbito cosmológico e no processo de colapso gravitacional. Em particular, analisamos o caso em que a densidade do vácuo possui uma dinâmica não trivial com a escala de energia típica do universo, que depende monotonamente do parâmetro de Hubble, decrescendo ao longo de toda a história cósmica. Nos referiremos a este modelo como modelo deflacionário. Nesse contexto, utilizando os primeiros termos da expansão para a densidade do vácuo, sugerida pela teoria do grupo de renormalização em espaço-tempos curvos, propomos um novo cenário cosmológico baseado numa densidade do vácuo dinâmica. O cenário proposto é completo no sentido de que o mesmo vácuo é responsável pelas duas fases aceleradas do universo, conectadas por uma fase de radiação e um estágio de domínio da matéria. Neste cenário o universo plano é não singular, iniciando sua evolução a partir de um estágio do tipo de Sitter e, portanto, toda a história cósmica ocorre entre duas fases de Sitter limites. Este modelo não apresenta o problema de horizonte, e nele a nucleossíntese cosmológica ocorre como no modelo de Friedmann, e embora este modelo seja muito próximo do modelo $\\Lambda$CDM, o grande acúmulo de observações no estágio recente do universo permitirão que este poda ser testado. Adicionalmente, mostraremos que generalizações do modelo deflacionário incluindo curvatura espacial apresentam propriedades e vantagens similares. Usando observações de $H(z)$, da luminosidade de supernovas tipo Ia, da função de crescimento linear das perturbações escalares, e da posição do pico das oscilações acústicas de bárions conseguimos vincular um dos parâmetros do modelo. Por outro lado, analisando a física do universo primordial, assumindo um vácuo não perturbado, conseguimos limitar um segundo parâmetro fazendo uso do índice espectral das perturbações escalares. Com o objetivo de fazer uma análise mais completa do modelo no âmbito cosmológico, analisamos também as possíveis restrições oriundas da validade da segunda lei da termodinâmica em sua forma generalizada (GSLT). Para isto investigamos a evolução tanto da entropia associada ao horizonte aparente do universo, que é um horizonte atrapante devido a que o escalar de Ricci é positivo, como do seu conteúdo material. Motivados pela forma como a singularidade primordial do universo é evitada devido aos efeitos do decaimento do vácuo, incluímos no presente trabalho outra linha de desenvolvimento: a análise dos estágios finais do processo de colapso gravitacional em presença de uma densidade do vácuo dinâmica. Centraremos esta análise na determinação de modelos que possam ou não evitar a formação de um buraco negro. Mostraremos que modelos com um termo de vácuo proporcional à densidade de energia total do sistema, não podem evitar a formação de uma singularidade no estágio final do processo de colapso. Adicionalmente obteremos correções para a massa colapsada, para o tempo de formação do horizonte e para o tempo de colapso como função dos parâmetros do modelo e da curvatura espacial. Por último analisaremos a influência de uma densidade do vácuo capaz de dominar sobre as outras componentes no regime de altas energias, mostrando que este tipo de dinâmica na densidade do vácuo evita a formação de um estado final singular. / The astronomical observations of the last 15 years revealed that the universe is currently undergoing an expanding accelerating phase. In the general relativity context is believed that dark energy, whose best candidate is the vacuum energy density $ho_v \\equiv \\Lambda/8\\pi G$, is the fuel responsible for the present accelerating stage. However, the so-called $\\Lambda$-term has two serious drawnbacks, namely: the cosmological constant problem and the coincidence problem. In order to alleviate the cosmological constant problem, many models adopt a dynamical $\\Lambda$ term, thereby allowing its decreasing throughout the cosmic history. In this kind of model, the total energy conservation law defined in terms of the energy momentum tensor requires an energy exchange between the vacuum and the material components of the universe, which also contributes to alleviate the coincidence problem. In the present thesis we discuss different consequences of an interacting vacuum component both in the cosmological scenario as well as in the process of gravitational collapse. In particular, in the cosmological domain, we examine the case where the vacuum has a nontrivial dynamics dependent on a typical energy scale, the Hubble parameter, that decreases in the course of the cosmic history. We will refer to this model as deflationary model. In this context, by using a truncated expansion for the vacuum energy density, as suggested by the renormalization group theory in curved space-time, we propose a new cosmological scenario based on a dynamical $\\Lambda$-term. The proposed scenario is complete in the sense that the same vacuum is responsible for both accelerating phases of the universe, which are linked by two subsequent periods of radiation and non-relativistic matter domination. In this scenario the flat universe is nonsingular and starts its evolution from an asymptotic de Sitter stage, so that the cosmic story takes place between two extreme de Sitter phases. The model is free of the horizon problem as well as of the \"graceful exit\" problem plaguing many inflationary variants. In addition, the cosmological nucleosynthesis occurs as in the Friedmann model and the observations in the latest stages of the universe can potentially differentiate between the deflationary and the standard $\\Lambda$CDM model. The generalizations including spatial curvature are aslo discussed in detail. On the other hand, by using the late time tests like type Ia supernovae, the redshift dependence of the Hubble parameter, $H(z)$, the linear growth function of scalar perturbations, and the peak position of baryon acoustic oscillations we have constrained the basic parameters of the model. Conversely, analyzing the physics of the primordial universe and assuming that the vacuum is a smooth component, we have also constrained the spectral index of scalar density perturbations. In order to establish a more complete analysis of our cosmological scenario, we also discuss the possible constraints arising from the validity of the generalized second law of thermodynamics, that is, by including the horizon thermodynamics. Since the apparent horizon of the universe behaves like a trapped horizon because the Ricci scalar is positive, we investigate the evolution of both the entropy of the material components and the entropy associated to the horizon. Motivated by the avoidance of the Big-Bang singularity due to the decaying vacuum effects, we have explored another line of development: the analysis of the final stages of gravitational collapse process in the presence of a dynamic vacuum. This analysis focused on the determination of models able to prevent or not the formation of a black hole. In this connection, we shown that the presence of an interacting vacuum proportional to the total energy density of the system does not prevent the formation of a singularity in the final stages of the collapsing process. In addition, we obtain corrections for the collapsed mass, the horizon time formation and the collapsing time as a function of the free parameters and the spatial curvature of the models. Finally, we have also analyzed the influence of a vacuum contribution which dominates the other components into the high energy limit (due to the presence of higher orders terms in the contraction rate), and shown that for this kind of models the growth of the vacuum energy density prevents the formation of the singularity.
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Shocks, Superbubbles, and Filaments: Investigations into Large Scale Gas Motions in Giant Molecular CloudsPon, Andrew Richard 25 April 2013 (has links)
Giant molecular clouds (GMCs), out of which stars form, are complex, dynamic systems, which both influence and are shaped by the process of star formation. In this dissertation, I examine three different facets of the dynamical motions within GMCs.
Collapse modes in different dimensional objects.
Molecular clouds contain lower dimensional substructures, such as filaments and sheets. The collapse properties of finite filaments and sheets differ from those of spherical objects as well as infinite sheets and filaments. I examine the importance of local collapse modes of small central perturbations, relative to global collapse modes, in different dimensional objects to elucidate whether strong perturbations are required for molecular clouds to fragment to form stars. I also calculate the dependence of the global collapse timescale upon the aspect ratio of sheets and filaments. I find that lower dimensional objects are more readily fragmented, and that for a constant density, lower dimensional objects and clouds with larger aspect ratios collapse more slowly. An edge-driven collapse mode also exists in sheets and filaments and is most important in elongated filaments. The failure to consider the geometry of a gas cloud is shown to lead to an overestimation of the star formation rate by up to an order of magnitude.
Molecular tracers of turbulent energy dissipation.
Molecular clouds contain supersonic turbulence that simulations predict will decay rapidly via shocks. I use shock models to predict which species emit the majority of the turbulent energy dissipated in shocks and find that carbon monoxide, CO, is primarily responsible for radiating away this energy. By combining these shock models with estimates for the turbulent energy dissipation rate of molecular clouds, I predict the expected shock spectra of CO from molecular clouds. I compare the results of these shock models to predictions for the emission from the unshocked gas in GMCs and show that mid-to-high rotational transitions of CO (e.g., J = 8 to 7), should be dominated by shocked gas emission and should trace the turbulent energy being dissipated in molecular clouds.
Orion-Eridanus superbubble.
The nearby Orion star forming region has created a large bubble of hot plasma in the local interstellar medium referred to as the Orion-Eridanus superbubble. This bubble is unusual in that it is highly elongated, is believed to be oriented roughly parallel to the galactic plane, and contains bright filamentary features on the Eridanus side. I fit models for a wind driven bubble in an exponential atmosphere to the Orion-Eridanus superbubble and show that the elongation of the bubble cannot be explained by such a model in which the scale height of the galactic disk is the typical value of 150 pc. Either a much smaller scale height must be adopted or some additional physics must be added to the model. I also show that the Eridanus filaments cannot be equilibrium objects ionized by the Orion star forming region. / Graduate / 0606 / andyrpon@gmail.com
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Efeitos de um vácuo dinâmico na evolução cósmica e no colapso gravitacional / Running vacuum effects in cosmic evolution and gravitational collapseEder Leonardo Duarte Perico 12 March 2015 (has links)
As observações astronômicas dos últimos 15 anos revelaram que o universo atualmente está expandindo aceleradamente. No contexto da relatividade geral se acredita que a energia escura, cujo melhor candidato é a densidade do vácuo ($\\Lambda/8\\pi G$), é o agente responsável por este estado acelerado. No entanto, o termo $\\Lambda$ tem duas sérias dificuldades: o problema da constante cosmológica e o problema da coincidência. Com o objetivo de aliviar o problema da constante cosmológica, muitos modelos adotam um termo $\\Lambda$ dinâmico, permitindo seu decrescimento ao longo de toda a história cósmica. Neste tipo de modelo, a equação de conservação do tensor momento energia total exige uma troca de energia entre a densidade do vácuo e as outras componentes energéticas do universo; o que também alivia o problema da coincidência. Neste trabalho discutimos diferentes consequências de um vácuo dinâmico no âmbito cosmológico e no processo de colapso gravitacional. Em particular, analisamos o caso em que a densidade do vácuo possui uma dinâmica não trivial com a escala de energia típica do universo, que depende monotonamente do parâmetro de Hubble, decrescendo ao longo de toda a história cósmica. Nos referiremos a este modelo como modelo deflacionário. Nesse contexto, utilizando os primeiros termos da expansão para a densidade do vácuo, sugerida pela teoria do grupo de renormalização em espaço-tempos curvos, propomos um novo cenário cosmológico baseado numa densidade do vácuo dinâmica. O cenário proposto é completo no sentido de que o mesmo vácuo é responsável pelas duas fases aceleradas do universo, conectadas por uma fase de radiação e um estágio de domínio da matéria. Neste cenário o universo plano é não singular, iniciando sua evolução a partir de um estágio do tipo de Sitter e, portanto, toda a história cósmica ocorre entre duas fases de Sitter limites. Este modelo não apresenta o problema de horizonte, e nele a nucleossíntese cosmológica ocorre como no modelo de Friedmann, e embora este modelo seja muito próximo do modelo $\\Lambda$CDM, o grande acúmulo de observações no estágio recente do universo permitirão que este poda ser testado. Adicionalmente, mostraremos que generalizações do modelo deflacionário incluindo curvatura espacial apresentam propriedades e vantagens similares. Usando observações de $H(z)$, da luminosidade de supernovas tipo Ia, da função de crescimento linear das perturbações escalares, e da posição do pico das oscilações acústicas de bárions conseguimos vincular um dos parâmetros do modelo. Por outro lado, analisando a física do universo primordial, assumindo um vácuo não perturbado, conseguimos limitar um segundo parâmetro fazendo uso do índice espectral das perturbações escalares. Com o objetivo de fazer uma análise mais completa do modelo no âmbito cosmológico, analisamos também as possíveis restrições oriundas da validade da segunda lei da termodinâmica em sua forma generalizada (GSLT). Para isto investigamos a evolução tanto da entropia associada ao horizonte aparente do universo, que é um horizonte atrapante devido a que o escalar de Ricci é positivo, como do seu conteúdo material. Motivados pela forma como a singularidade primordial do universo é evitada devido aos efeitos do decaimento do vácuo, incluímos no presente trabalho outra linha de desenvolvimento: a análise dos estágios finais do processo de colapso gravitacional em presença de uma densidade do vácuo dinâmica. Centraremos esta análise na determinação de modelos que possam ou não evitar a formação de um buraco negro. Mostraremos que modelos com um termo de vácuo proporcional à densidade de energia total do sistema, não podem evitar a formação de uma singularidade no estágio final do processo de colapso. Adicionalmente obteremos correções para a massa colapsada, para o tempo de formação do horizonte e para o tempo de colapso como função dos parâmetros do modelo e da curvatura espacial. Por último analisaremos a influência de uma densidade do vácuo capaz de dominar sobre as outras componentes no regime de altas energias, mostrando que este tipo de dinâmica na densidade do vácuo evita a formação de um estado final singular. / The astronomical observations of the last 15 years revealed that the universe is currently undergoing an expanding accelerating phase. In the general relativity context is believed that dark energy, whose best candidate is the vacuum energy density $ho_v \\equiv \\Lambda/8\\pi G$, is the fuel responsible for the present accelerating stage. However, the so-called $\\Lambda$-term has two serious drawnbacks, namely: the cosmological constant problem and the coincidence problem. In order to alleviate the cosmological constant problem, many models adopt a dynamical $\\Lambda$ term, thereby allowing its decreasing throughout the cosmic history. In this kind of model, the total energy conservation law defined in terms of the energy momentum tensor requires an energy exchange between the vacuum and the material components of the universe, which also contributes to alleviate the coincidence problem. In the present thesis we discuss different consequences of an interacting vacuum component both in the cosmological scenario as well as in the process of gravitational collapse. In particular, in the cosmological domain, we examine the case where the vacuum has a nontrivial dynamics dependent on a typical energy scale, the Hubble parameter, that decreases in the course of the cosmic history. We will refer to this model as deflationary model. In this context, by using a truncated expansion for the vacuum energy density, as suggested by the renormalization group theory in curved space-time, we propose a new cosmological scenario based on a dynamical $\\Lambda$-term. The proposed scenario is complete in the sense that the same vacuum is responsible for both accelerating phases of the universe, which are linked by two subsequent periods of radiation and non-relativistic matter domination. In this scenario the flat universe is nonsingular and starts its evolution from an asymptotic de Sitter stage, so that the cosmic story takes place between two extreme de Sitter phases. The model is free of the horizon problem as well as of the \"graceful exit\" problem plaguing many inflationary variants. In addition, the cosmological nucleosynthesis occurs as in the Friedmann model and the observations in the latest stages of the universe can potentially differentiate between the deflationary and the standard $\\Lambda$CDM model. The generalizations including spatial curvature are aslo discussed in detail. On the other hand, by using the late time tests like type Ia supernovae, the redshift dependence of the Hubble parameter, $H(z)$, the linear growth function of scalar perturbations, and the peak position of baryon acoustic oscillations we have constrained the basic parameters of the model. Conversely, analyzing the physics of the primordial universe and assuming that the vacuum is a smooth component, we have also constrained the spectral index of scalar density perturbations. In order to establish a more complete analysis of our cosmological scenario, we also discuss the possible constraints arising from the validity of the generalized second law of thermodynamics, that is, by including the horizon thermodynamics. Since the apparent horizon of the universe behaves like a trapped horizon because the Ricci scalar is positive, we investigate the evolution of both the entropy of the material components and the entropy associated to the horizon. Motivated by the avoidance of the Big-Bang singularity due to the decaying vacuum effects, we have explored another line of development: the analysis of the final stages of gravitational collapse process in the presence of a dynamic vacuum. This analysis focused on the determination of models able to prevent or not the formation of a black hole. In this connection, we shown that the presence of an interacting vacuum proportional to the total energy density of the system does not prevent the formation of a singularity in the final stages of the collapsing process. In addition, we obtain corrections for the collapsed mass, the horizon time formation and the collapsing time as a function of the free parameters and the spatial curvature of the models. Finally, we have also analyzed the influence of a vacuum contribution which dominates the other components into the high energy limit (due to the presence of higher orders terms in the contraction rate), and shown that for this kind of models the growth of the vacuum energy density prevents the formation of the singularity.
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