Time asymmetry

Lyons, Glenn

January 1993

No description available.

530.1

Quantum cosmology; Scalar field model

Scalar Fields and Alternatives in Cosmology and Black Holes

Leith, Ben Maitland

January 2007

Extensions to general relativity are often considered as possibilities in the quest for a quantum theory of gravity on one hand, or to resolve anomalies within cosmology on the other. Scalar fields, found in many areas of physics, are frequently studied in this context. This is partly due to their manifestation in the effective four dimensional theory of a number of underlying fundamental theories, most notably string theory. This thesis is concerned with the effects of scalar fields on cosmological and black hole solutions. By comparison, an analysis of an inhomogeneous cosmological model which requires no extensions to general relativity is also undertaken. In chapter three, examples of numerical solutions to black hole solutions, which have previously been shown to be linearly stable, are found. The model includes at least two scalar fields, non-minimally coupled to electromagnetism and hence possesses non-trivial contingent primary hair. We show that the extremal solutions have finite temperature for an arbitrary coupling constant. Chapter four investigates the effects of higher order curvature corrections and scalar fields on the late-time cosmological evolution. We find solutions which mimic many of the phenomenological features seen in the post-inflation Universe. The effects due to non-minimal scalar couplings to matter are also shown to be negligible in this context. Such solutions can be shown to be stable under homogeneous perturbations. Some restrictions on the value of the slope of the scalar coupling to the Gauss-Bonnet term are found to be necessary to avoid late-time superluminal behaviour and dominant energy condition violation. A number of observational tests are carried out in chapter five on a new approach to averaging the inhomogeneous Universe. In this "Fractal Bubble model" cosmic acceleration is realised as an apparent effect, due to quasilocal gravitational energy gradients. We show that a good fit can be found to three separate observations, the type Ia supernovae, the baryon acoustic oscillation scale and the angular scale of the sound horizon at last scattering. The best fit to the supernovae data is χ² ≃ 0:9 per degree of freedom, with a Hubble parameter at the present epoch of H0 = 61:7+1:4 -1:3 km sec⁻¹ Mpc⁻¹ , and a present epoch volume void fraction of 0:76 ± 0:05.

Cosmology

Black Holes

Supernova

Scalar Field

Gravity

The Prehispanic Tewa World: Space, Time, and Becoming in the Pueblo Southwest

Duwe, Samuel Gregg

January 2011

Cosmology -- the theory, origin, and structure of the universe -- underlies and informs thought and human action and manifests in people's material culture. However, the theoretical and methodological tools needed to understand cosmological change over archaeological time scales remains underdeveloped. This dissertation addresses the history of the Pueblo people of the American Southwest, specifically the Tewa of the northern Rio Grande region in modern New Mexico, to identify and explain cosmological change in the context of dramatic social and residential transformation.The Great Drought and resulting abandonment of much of the northern Southwest in the late-1200s acted as a catalyst for a complex reorganization of the Pueblo world as displaced migrant groups interacted with existing communities, including people of the Rio Grande region. I argue that this period of immigration, reorganization, and subsequent population coalescence of disparate people, with different world views and histories, resulted in a unique construction of the cosmos and, eventually, the Tewa identity and history that the Spanish encountered in the late 1500s. The resulting Tewa cosmology recorded in twentieth century ethnography, while heavily influenced by histories of conquest and colonization, is therefore a palimpsest of the memories, identities, and histories of disparate peoples brought together by the events of migration and coalescence.Using data collected from architectural mapping, pottery analysis, ceramic compositional analysis, and dendrochronology, I infer a history of settlement and interaction between and within possibly disparate ancestral Tewa groups in the northern Rio Grande region. I then interpret ritual landscape data with respect to cosmological change, focusing on natural and cultural (shrines and rock art) features immediately adjacent to the village.I argue that new cosmologies were developed through negotiation of worldview between disparate peoples displaced by the mass-depopulation of the northern Southwest. The ethnographic Tewa cosmology has roots in multiple traditions but is innovative and unique in the context of the larger Pueblo world. However, because the majority of the Pueblo world underwent similar residential, social, ritual, and cosmological transformation from A.D. 1275-1600, a Tewa case study has broad implications for the remainder of the Pueblo Southwest.

Pueblo

religion

southwest

Anthropology

cosmology

landscape

Equilibrium and non-equilibrium aspects of early universe phase transitions

Antunes, Nuno Dias

January 1998

No description available.

530.1

Quantum fluctuations

Cheetham, Gareth John

January 1995

No description available.

530.1

Dynamics of inflation

Mazumdar, Anupam

January 2000

No description available.

523.01

On the influence of the cosmological constant on trajectories of light and associated measurements

Lebedev, DMITRI

01 October 2013

In this thesis we review and build on the common methods used to analyze null geodesics in Schwarzschild de Sitter space. We present a general technique which allows finding measurable intersection angles of null trajectories analytically, and as one of its applications we establish a general relativistic aberration relationship. The tools presented are used to analyze some standard setups of gravitational deflection of light and gain a clear understanding of the role that the cosmological constant, Λ, plays in gravitational lensing phenomena. Through reviewing some recent papers on the topic with the present results in mind, we attempt to explain the major sources of disagreement in the ongoing debate on the subject, which started with Rindler and Ishak’s original paper, regarding the influence of Λ on lensing phenomena. To avoid ambiguities and room for misunderstanding we present clear definitions of the quantities used in the present analysis as well as in other papers we discuss. / Thesis (Master, Physics, Engineering Physics and Astronomy) -- Queen's University, 2013-09-30 21:18:26.762

gravity

cosmological constant

bending of light

cosmology

Paul Tillich: His Anthropology As Key To The Structure Of His Thought

Tollefson, Terry Ray

05 1900

Permission from the author to digitize this work is pending. Please contact the ICS library if you would like to view this work.

Tillich, Paul, 1886-1965

Anthropology

Cosmology

Simulating weak gravitational lensing for cosmology

Kiessling, Alina Anne

January 2011

This thesis will present a new cosmic shear analysis pipeline SUNGLASS (Simulated UNiverses for Gravitational Lensing Analysis and Shear Surveys). SUNGLASS is a pipeline that rapidly generates simulated universes for weak lensing and cosmic shear analysis. The pipeline forms suites of cosmological N-body simulations and performs tomographic cosmic shear analysis using a novel line-of-sight integration through the simulations while saving the particle lightcone information. Galaxy shear and convergence catalogues with realistic 3-D galaxy redshift distributions are produced for the purposes of testing weak lensing analysis techniques and generating covariance matrices for data analysis and cosmological parameter estimation. This thesis presents a suite of fast medium-resolution simulations with shear and convergence maps for a generic 100 square degree survey out to a redshift of z = 1.5, with angular power spectra agreeing with the theoretical expectations to better than a few percent accuracy up to ℓ = 103 for all source redshifts up to z = 1.5 and wavenumbers up to ℓ = 2000 for source redshifts z ≥ 1.1. A two-parameter Gaussian likelihood analysis of Ωm and σ8 is also performed on the suite of simulations for a 2-D weak lensing survey, demonstrating that the cosmological parameters are recovered from the simulations and the covariance matrices are stable for data analysis, with negligible bias. An investigation into the accuracy of traditional Fisher matrix calculations is presented. Fisher Information Matrix methods are commonly used in cosmology to estimate the accuracy that cosmological parameters can be measured with a given experiment, and to optimise the design of experiments. However, the standard approach usually assumes both data and parameter estimates are Gaussian-distributed. Further, for survey forecasts and optimisation it is usually assumed the power-spectra covariance matrix is diagonal in Fourier-space. But in the low-redshift Universe, non-linear mode-coupling will tend to correlate small-scale power, moving information from lower to higher-order moments of the field. This movement of information will change the predictions of cosmological parameter accuracy. In this thesis, the loss of information is quantified by comparing näıve Gaussian Fisher matrix forecasts with a Maximum Likelihood parameter estimation analysis of the suite of mock weak lensing catalogues derived from the SUNGLASS pipeline, for 2-D and tomographic shear analyses of a Euclid-like survey. In both cases the 68% confidence area of the Ωm − σ8 plane is found to increase by a factor 5. However, the marginal errors increase by just 20 to 40%. A new method is proposed to model the effects of non-linear shear-power mode-coupling in the Fisher Matrix by approximating the shear-power distribution as a multivariate Gaussian with a covariance matrix derived from the mock weak lensing survey. The findings in this thesis show that this approximation can reproduce the 68% confidence regions of the full Maximum Likelihood analysis in the Ωm − σ8 plane to high accuracy for both 2-D and tomographic weak lensing surveys. Finally, three multi-parameter analyses of (Ωm, σ8, ns), (Ωm, σ8, ns, ΩΛ)and (Ωm, σ8, h, ns, w0, wa) are performed to compare the Gaussian and non-linear mode-coupled Fisher matrix contours. The multi-parameter volumes of the 1σ error contours for the six-parameter non-linear Fisher analysis are consistently larger than for the Gaussian case, and the shape of the 68% confidence volume is modified. These results strongly suggest that future Fisher Matrix estimates of cosmological parameter accuracies should include mode-coupling effects.

520

Dynamical Stability of Planetary Systems

Stergiopoulou, Aikaterini

January 2017

The study of dynamical stability in planetary systems has become possible during the last few decades due to the development of numerical methods for long-term integrations of N-body systems. Since the 90’s the number of exoplanet detections has been increased significantly, making the simulations of other real planetary systems besides the Solar System feasible. One of the exciting new-found worlds is the system Kepler-11. Six planets which are located very close to each other orbit a solar-type star. In this project we first investigate the behavior of Kepler-11 when we change some of the initial conditions of the outermost planet of the system and then we approximate the Red Giant phase of solar-type stars in order to see how the planetary orbits are altered. For the first part we run three series of simulations (groups A,B,C). Each group has a different value for the mean density of planet Kepler-11g (1.0,1.5,2.0 g/cm 3 ). We run simulations for 36 different combinations of mass and eccentricity of planet Kepler-11g for each group. In nine configurations all six planets of the system continue to orbit the star until the end of the simulations. These nine stable configurations of Kepler-11 are used in the second part where we implement a constant mass-loss rate for the star which results in 30% mass loss after 30 million years, trying to approximate that way the mass loss of solar-type stars in Red Giant Branch. We also run nine simulations of a hypothetical system consisting only of the Sun, Earth and Jupiter where we implement the constant mass-loss rate to the Sun. In the Kepler-11 system, the orbits of planets Kepler-11g and Kepler-11e change by ∼45% and ∼54% respectively, after 30 million years, due to the mass loss of the star, while in the hypothetical planetary system the orbits of the two planets change by ∼43%. The study of orbits and how they move outward during the Post-Main Sequence evolution of stars is essential for our understanding of the existence of a Habitable Zone, not just around stars in Main-Sequence phase, but also around stars in late stages of their evolution.

Astronomy, Astrophysics and Cosmology

Astronomi, astrofysik och kosmologi