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Neutral hydrogen intensity mapping on small scales using MeerKATTownsend, Mogamad-Junaid January 2021 (has links)
>Magister Scientiae - MSc / In the post-reionisation universe, intensity mapping (IM) with the 21 cm line of neutral hydrogen (HI) provides a potential means of probing the large-scale structure of the universe. With such a probe, a wide variety of interesting phenomena such as the Baryon Acoustic Oscillations (BAO) and Redshift Space Distortions (RSD) can be studied. The MeerKAT telescope has the potential to make full use of this technique, especially in the single-dish mode, which will probe the scales relevant to BAO and RSD. A useful complementary of this is HI IM with MeerKAT in interferometer-mode, which will enable the extraction of cosmological information on semi-linear and small scales. In this study, full end-to-end simulations of interferometric observations with MeerKAT for HI IM were developed. With this, the power spectrum extraction was analysed using the foreground avoidance technique. This took into account the foreground wedge from point source contamination extracted from real MIGHTEE COSMOS data, as well as RFI flagging. The errors on the power spectrum estimator were then calculated through a Monte Carlo process using 1000s of realisations of both the thermal noise and HI signal. In doing so, precision constraints on the HI power spectrum are found at z = 0:27 on scales 0:4 < k < 10 Mpc-1 for mock visibility data sets which contain the HI signal contaminated by noise, mimicking the MIGHTEE COSMOS field for total observation times & 20 hours. These results illustrate the potential of doing precision cosmology with MeerKAT’s MIGHTEE survey and interferometer-mode HI IM.
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Probing large-scale structure with the SKAO and other cosmological surveysViljoen, Jan-Albert January 2022 (has links)
Philosophiae Doctor - PhD / In recent history there have been several advances in cosmology, which has significantly
shaped our understanding of the Universe. The current leading theory is called ΛCDM,
which can successfully model the expansion of the Universe from a primordial state
and describe the dynamics of its contents, thereby resulting in the large-scale structure
present today. The model is based on general relativity, that describes gravitational
interaction as the curvature of a four-dimensional manifold called space-time. However,
despite the many successes of ΛCDM, there are a number of things that need further
investigation.
The Cosmic Microwave Background (CMB) is the oldest observable radiation in
the Universe, and this cosmological relic contains a detectable structure. The process
leading up to the CMB determines the initial conditions of ΛCDM, but is still poorly
understood. It is widely accepted that inflation was responsible for the rapid expansion
after the Big Bang, although this is yet to be verified experimentally. The distribution
of the primordial potential is imprinted on ultra-large scales of the matter distribution,
which offers an important insight into uncovering this mystery.
In addition to the primordial Universe, there are other concepts that still puzzle us in
ΛCDM itself. The fact that we have been unable to directly detect and explain these dark
components (that make up around 96% of the Universe) has prompted several theorists
to consider alternative cosmological models. Therefore, testing general relativity
and ΛCDM is still an essential part of cosmological research. A key observational
discriminant between general relativity and modified theories of gravity is the rate at
which the large-scale structure grows from small perturbations. The relativistic effects
(or light-cone effects) expected in general relativity also offer an independent test of
the gravitational model.
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The study of cosmological radio backgrounds with the Sunyaev-Zel'dovich effectEmritte, Mohammad Shehzad January 2017 (has links)
A thesis submitted to the Faculty of Science,
University of Witwatersrand,
in the ful lment of the requirements for the degree of
Doctor of Philosophy
Johannesburg, South Africa, 2017. / According to the standard model of cosmology, the Universe has evolved from a thermal bath
of elementary particles and photons towards one comprising of collapsed structures such as
stars, galaxies and clusters of galaxies. The Cosmic Microwave Background (CMB) spectrum
and its angular anisotropy across the sky contain information on the physical processes,
matter distribution and evolution of the Universe across cosmic time. Primordial spectral
distortions of the CMB and its anisotropy can be studied through the inverse comptonization
process occuring in cosmic structures, known as the Sunyaev-Zel'dovich e ect (SZE). This
present study demonstrates how the SZE can be used to obtain information on the 21
cm background produced between the Dark Ages (DA) and the Epoch of Reionization
(EoR), on Non-Planckian (NP) modi cations of the CMB due to plasma frequency at the
recombination epoch, and on the anisotropy of the CMB at cluster locations, through the
study of the polarization of the SZE. To these aims, a full relativistic approach is employed,
that allows us to calculate the spectra of the SZE and its polarization component with high
precision, and allows to calculate it for any kind of electron population (thermal or nonthermal
plasma), and for an input spectrum that can deviate from the standard black-body
spectrum.
The SZE-21cm, which is the comptonized spectrum of the modi ed CMB due to physical
processes occuring during the DA and the EoR, is calculated for four models of the 21-cm
background. A full spectral analysis of the signal is performed and the importance of
relativistic e ects are highlighted. The results demonstrate that relativistic e ects are nonzero
over the entire frequency spectrum and hence cannot be ignored, particularly for hot
clusters. It is found that the amplitude of the SZE-21cm signal is of the order of Jy and
is within the reach of the SKA instrument. Clusters with high temperature and optical
depth are optimal targets to search for the SZE-21cm signal. The SKA can measure the
signal in the frequency interval 75-90 MHz for clusters with temperature higher than 5 keV.
Discerning the SZE-21cm from the standard SZE can be achieved using the SKA depending
on the 21-cm background model for temperatures > 10 keV.
Using CMB spectral data at both low and high frequencies, upper limits (206, 346 and
418 MHz at 1, 2, 3 con dence level) are placed on NP e ects associated with a non-zero
plasma frequency at the recombination epoch. The SZENP is derived for a CMB spectrum
modi ed due to plasma e ects using these upperlimits and a unique spectral feature is
obtained. A peak occures at the plasma frequency in the SZENP independent of cluster
parameters and the possibility of measuring the plasma frequency with the SKA and eVLA
is shown. Plasma e ects are also investigated on the spectrum of the cosmological 21-cm
background and it is found that such an e ect is important to consider when recovering the
history of the Universe during these epochs.
Polarization is a natural outcome of inverse Compton (IC) scattering and the anisotropy
of the CMB plays a big role in the production of polarization in Comptonization process.
The SZE polarization associated with the anisotropy of the CMB is derived in the full relativistic
regime for any general electron distribution. The spectral shapes of the Stokes
parameters induced by the IC scattering of the multipoles of the CMB for thermal and
non-thermal electrons are derived, focusing mainly on the quadrupole and octupole which
provide the largest possible detectable signals in cosmic structures. Our results demonstrate
the implication of relativistic e ects, which become important for high temperature
or non-thermal cluster environments. When relativistic e ects are accounted for, all the
multipoles of the CMB are involved in the production of polarization. The octupole induced
polarization spectrum reveals the existence of a cross-over frequency which is dependent
on cluster parameters such as temperature, minimum momentum and spectral index. The
possibilities to disentangle the quadrupole spectrum from the octupole one are discussed,
which would allow the measurments of these multipoles at cluster locations. The generality
of our approach allows us to calculate the SZE polarization spectra of the Bullet cluster
using multifrequency SZE data in intensity and compare the results with the sensitivities of
the SKA, ALMA, Millimetron and CORE++ instruments.
Although the e ects that we studied here are small, however, they are still within the
detection limits of the SKA, due to its very high sensitivity. Therefore, the SKA will play
a big role in the study of cosmological radio backgrounds by providing high precision SZE
data. / LG2018
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Experimental and Numerical Investigations of Granular Dynamics in MicrogravityJarmak, Stephanie 01 January 2020 (has links)
During the first stages of planet formation small particles (~0.1 – 1 µm) in the protoplanetary disk collide at low relative velocities (less than 1 m/s) and tend to aggregate into cm-size "pebbles" through a combination of electrostatic interactions and gravitational streaming instabilities. Particles in this size regime also compose a layer of regolith on small, airless bodies that evolves under conditions very different than those on Earth. Characterizing the response of regolith to low-energy impacts in a microgravity environment is therefore critical to our understanding of the processes that lead to the formation of these objects and our ability to develop safe operation procedures on their surfaces. Flight-based microgravity experiments investigating low-velocity collisions of cm-size projectiles into regolith have revealed that certain impact events result in mass transfer from the target regolith onto the surface of the projectile. Characterizing the key parameters and their interactions that produce these events have important implications for the role of energy dissipation and accretion in planet formation processes and understanding the mechanical behavior of granular media composing the surfaces of small bodies. I carried out experimental and numerical campaigns designed to investigate these mass transfer events and found that accretion outcomes differ significantly depending on whether the projectile is launched into granular material or initially at rest before pulling away from the granular bed. I found that interaction effects between various parameters and the balance of the experiment design significantly influence mass transfer outcomes and must be taken into account for future experiment designs. I also present my contributions to a CubeSat mission that will provide the opportunity to observe tens of thousands of collisions between particles in the velocity and size regime relevant to the earliest stages of planet formation.
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Tests of the Planck cosmology at high and low redshiftsLemos Portela, Pablo January 2019 (has links)
The inflationary ΛCDM cosmology currently provides an accurate description of the Universe. It has been tested using several observational techniques over a wide redshift range, and it provides a good fit to most of them. In addition, it is a surprisingly economical model, requiring only six parameters to characterize the background cosmology and its fluctuations. In this model, the Universe is dominated by a cosmological constant Λ driving an accelerated expansion, and by cold dark matter. The strongest constraints on parameters to date come from observations of the temperature and polarization anisotropies of the cosmic microwave background measured by the Planck satellite. There are, however, indications of features in the Planck power spectra, possible differences with high redshift ground-based CMB experiments, and 'tensions' between Planck and low redshift measurements of the Hubble constant and weak gravitational lensing. In this thesis, we review possible tensions and extensions to the Planck cosmology, at both high and low redshifts. We begin with the high redshift analysis, using the Planck data to test models which introduce oscillatory features in the primordial power spectrum. We also study possible departures from slow roll inflation using the generalized slow-roll formalism, which allows for order unity deviations. Although we find models which give marginal improvements on the temperature or polarization power spectra, the combination of temperature and polarization is found to be consistent with a featureless power-law primordial spectrum. We then focus on measurements of the polarized CMB sky by the South Pole Telescope collaboration, who report tension between their measurements and the ΛCDM cosmology and with the cosmological parameters determined by Planck. We find evidence of a high χ2 in the SPTpol spectra which is unlikely to be cosmological. We report consistency between the Planck and SPTpol polarization spectra over the multipoles accessible to Planck (l ∼< 1500). We then investigate tension at low redshifts. We begin with weak gravitational lensing in which a number of surveys have suggested that the amplitude of the fluctuation spectra is lower than the Planck value. We review the small-angle approximations commonly used in galaxy weak lensing analyses and their effect on cosmological parameters. We find that these approximations are perfectly adequate for present and near future experiments. We find internal inconsistencies in the recent KiDS-450 analysis involving photometric redshifts and the KiDS covariance matrix at large scales. Finally, we investigate the difference between measurements of the present day expansion rate of the Universe. We apply a novel parameterization of the inverse distance ladder to determine the present date value of the Hubble parameter H0, which assumes General Relativity but makes no further assumptions about systematic errors or the nature of dark energy. Our analysis uses baryon acoustic oscillation data and Type Ia Supernovae to constrain the expansion history assuming a value of the sound horizon determined from the CMB. Our results are in tension with recent direct determinations of H0. We conclude that this tension, if real, cannot be solved by modifications of the ΛCDM model at late times. Instead, we would require a modification of the theory at early times which reduces the sound horizon. We conclude that at this time there is no compelling evidence that conflicts with the ΛCDM cosmology either at low or at high redshifts.
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Lyman-alpha scattering in the intergalactic medium during the epoch of reionisationHiggins, Jonathan January 2012 (has links)
We examine resonant scattering of Lyα (Lyman-alpha) photons in the neutral hydrogen Intergalactic Medium (IGM) at high redshift. Lyα scattering plays a key role in the 21cm emission/absorption against the Cosmic Microwave Background via the 'Wouthuysen-Field Effect' Knowledge of the strength of Lyα scattering induced by the first sources will constitute a significant step in predicting and understanding the eventual observations of the impact of these objects on the signal from the IGM during the Epoch of Reionisation (EoR), using planned facilities such as the Square Kilometre Array. A quantitative analysis of the scattering rate requires formulation and solution of the radiative transfer equation for the system. We consider radiative transfer of Lyα scattering far from a source in the homogeneous expanding IGM for photons that free stream until scattering in the blue wing of the local line profile: we describe an approximation that ignores spatial diffusion of photons and assumes a locally homogeneous scattering medium, allowing the calculation of simple analytic solutions to examine the dependence of the local scattering rate on various physical effects such as local expansion/contraction, and extend our approach to determine time-dependent solutions. The more complex problem of Lyα photons scattering in both frequency and space within a spherically symmetric medium is subsequently solved for several test problems using both Monte Carlo methods and a method based on the ray and moment radiative transfer equations following an approach due to Mihalas et al. [1975, 1976]. We examine local Lyα scattering around a continuum source in the homogeneous expanding IGM using both methods and compare our results with an analytic solution in the zero-temperature diffusion regime derived from an analogous solution for a monochromatic source found by Loeb and Rybicki [1999]. Our results are used to make estimates of the resulting size of the spherical region around the source that is rendered detectable via 21cm observations against the CMB background. We also examine cases with different density and velocity profiles and determine the effect on the scattering rate.
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The relationship between type Ia supernovae and their host galaxiesPan, Yen-Chen January 2014 (has links)
This thesis studies the relationship between type Ia supernovae (SNe Ia) and their host galaxies. The sample consists of 527 SNe Ia with redshift z<0.09 discovered by the Palomar Transient Factory (PTF). We obtained high-quality photometric and spectroscopic data of the host galaxies and determined their stellar mass M<sub>stellar</sub>, star formation rate (SFR), gas-phase/stellar metallicity, stellar age and SN offset. In the first part of the analysis, we compare the SN Ia photometric properties to the host parameters. Strong correlations between the SN Ia light-curve width (stretch) and the host age/mass/metallicity are found: fainter, faster-declining events tend to be hosted by older/massive/metal-rich galaxies. There is also some evidence that redder SNe Ia explode in higher metallicity galaxies. SNe Ia in higher-mass/metallicity galaxies also appear brighter after stretch/colour corrections than their counterparts in lower mass hosts, and the stronger correlation is with gas-phase metallicity suggesting this may be the more important variable. We also compare the host stellar mass distribution to that in galaxy targeted SN surveys and the high-redshift untargeted Supernova Legacy Survey (SNLS). The difference between each stellar mass distribution can be explained by an evolution in the galaxy stellar mass function, coupled with a SN delay-time distribution proportional to t<sup>-1</sup>. Finally, we found no significant difference in the mass-metallicity relation of our SN Ia hosts compared to field galaxies, suggesting any metallicity effect on the SN Ia rate is small. In the second part of the analysis, we compare the SN spectral features to the host parameters. We find that SNe Ia with higher Si ii λ6355 velocities tend to explode in more massive galaxies. We study the strength of the high-velocity component of the Ca ii NIR absorption, and find that SNe Ia with a stronger high-velocity component are preferentially hosted by galaxies with a low M<sub>stellar</sub>, a blue colour, and a high SFR, and are therefore likely to arise from the youngest progenitor systems. When combined with other studies, our results support the scenario that these high-velocity features are related to an interaction between the SN ejecta and a circumstellar medium (CSM) local to the SN.
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Re-embodying leadership through a re-examination of the sacredYoung, Alison Margaret Grieg January 2014 (has links)
The last couple of decades have witnessed an exponential increase of interest in religion and spirituality in the academic disciplines of leadership and organization. Some scholars argue that this interest is prone to neglect analysis of Western religion’s historical origins and therefore of what may be its repressed influences on leadership and organizational practices. Others, that this revived focus on the sacred may be limited by an over-reliance on too narrow a theology rooted within a singular (Judeo-Christian) cosmology. I seek to both speak to and expand the concerns of such previous research. I do this by introducing ecofeminism as a theoretical framework for a critical analysis of the macro level of what has already been framed as the repressed influence of mainstream religious orthodoxy within the field of leadership studies. Building upon the perspectives provided by ecofeminism and feminist spirituality I extend the aforementioned concerns by suggesting that some of the ethics within the Judeo-Christian cosmology itself bear some relationship to and responsibility in crises relating to environmental sustainability and social justice. I explore a number of related themes, arguing in particular that the demotion of nature and partnership with what might be described as the divine feminine within Western culture are not only linked but also generate profound dysfunction, in both leadership and organization. In the second section I present empirical data at a micro level, collected within a contemporary spiritual community where both nature and the divine feminine play central roles in its cosmology. The School of Movement Medicine functions as a financially successful business organization dedicated to the encouragement of spiritual fulfillment, ecological sustainability and social justice. The practices it teaches are specifically designed to assist those who engage with them to take responsibility for responding to the individual, societal and global challenges that lie before us - aiming, in other words to make leaders out of members. My hope is that these explorations may answer some of the calls of previous work to broaden representation within the leadership and spirituality field, as well as enriching its theory and practice with greater potential to generate increased levels of social justice, environmental sustainability and human fulfillment.
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Dark Matter: Signs and Genesis/ Matière noire: Signes et GenèseLopez Honorez, Laura 26 June 2007 (has links)
<p align="justify">The success of Big Bang Nucleosynthesis (BBN) combined with the detailed analysis of the small imperfections of the Cosmic Microwave Background blackbody spectrum lead to the conclusion that most of the matter content of our universe is made of some non-baryonic material, the dark matter!</p>
<p align="justify">In this thesis, we review the compiling indications of dark matter and the so-called freeze-out mechanism which may settle the relic density of the species in the framework of the standard Big Bang model. We also examine principally two methods of detection of dark matter, direct and indirect detection searches.</p>
<p align="justify">Let us stress that the Standard Model on its own is unable to provide enough aspirants for the role of dark matter. As a consequence, one has to dig into the tremendous domain of physics "Beyond the Standard Model" in order to have a chance to elucidate the problem of the missing mass.</p>
<p align="justify">In this thesis in particular, we consider the Inert Doublet Model (IDM) which includes an additional Higgs doublet, enclosing two neutral scalars candidates for dark matter. We invoke the Standard freeze-out mechanism for the production of dark matter. We get then dark matter candidates in two rather separate mass ranges, one between 40 and 80 GeV, the other one between 400 GeV and 1 TeV. We also show that dark matter annihilation at the galactic center can be at the origin of a gamma-ray flux which can be probed by the future GLAST experiment.</p>
<p align="justify">We address a low reheating temperature scenario for the genesis of dark matter in a Left-Right symmetric extension of the Standard Model. The candidate for dark matter is a MeV right-handed neutrino and we show that a baryon-dark matter interaction at the galactic center can be the source of the low energy positrons responsible for the 511 keV gamma-ray excess observed by the INTEGRAL experiment in the galactic bulge region.</p>
<p align="justify">Finally, prompted by the possibility to explain the baryon and dark matter rather similar abundances by one single "Matter Genesis" mechanism, we study a non-thermal production mechanism for dark matter. The framework is also Left-Right symmetric and dark candidate is a ~3 GeV right handed neutrino.</p>
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A fluctuation analysis for optical cluster galaxiesWindridge, David January 2000 (has links)
No description available.
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