2026-05-23T20:22:17Zhttps://keep.lib.asu.edu/oai/requestoai:keep.lib.asu.edu:node-1563092024-12-20T18:25:12Zoai_pmh:alloai_pmh:repo_items156309
https://hdl.handle.net/2286/R.I.49166
http://rightsstatements.org/vocab/InC/1.0/
All Rights Reserved
2018
2020-05-07T08:30:42
xiv, 156 pages : color illustrations
Doctoral Dissertation
Academic theses
Text
eng
Kolopanis, Matthew John
Bowman, Judd
Mauskopf, Philip
Lunardini, Cecilia
Chamberlin, Ralph
Vachaspati, Tanmay
Arizona State University
Partial requirement for: Ph.D., Arizona State University, 2018
Includes bibliographical references (pages 116-139)
Field of study: Physics
The Cosmic Microwave Background (CMB) has provided precise information on the evolution of the Universe and the current cosmological paradigm. The CMB has not yet provided definitive information on the origin and strength of any primordial magnetic fields or how they affect the presence of magnetic fields observed throughout the cosmos. This work outlines an alternative method to investigating and identifying the presence of cosmic magnetic fields. This method searches for Faraday Rotation (FR) and specifically uses polarized CMB photons as back-light. I find that current generation CMB experiments may be not sensitive enough to detect FR but next generation experiments should be able to make highly significant detections. Identifying FR with the CMB will provide information on the component of magnetic fields along the line of sight of observation.<br/><br/>The 21cm emission from the hyperfine splitting of neutral Hydrogen in the early universe is predicted to provide precise information about the formation and evolution of cosmic structure, complementing the wealth of knowledge gained from the CMB. <br/><br/>21cm cosmology is a relatively new field, and precise measurements of the Epoch of Reionization (EoR) have not yet been achieved. In this work I present 2σ upper limits on the power spectrum of 21cm fluctuations (Δ²(k)) probed at the cosmological wave number k from the Donald C. Backer Precision Array for Probing the Epoch of Reionization (PAPER) 64 element deployment. I find upper limits on Δ²(k) in the range 0.3 < k < 0.6 h/Mpc to be (650 mK)², (450 mK)², (390 mK)², (250 mK)², (280mK)², (250 mK)² at redshifts z = 10.87, 9.93, 8.91, 8.37, 8.13 and 7.48 respectively<br/><br/>Building on the power spectrum analysis, I identify a major limiting factor in detecting the 21cm power spectrum.<br/><br/>This work is concluded by outlining a metric to evaluate the predisposition of redshifted 21cm interferometers to foreground contamination in power spectrum estimation. This will help inform the construction of future arrays and enable high fidelity imaging and<br/><br/>cross-correlation analysis with other high redshift cosmic probes like the CMB and other upcoming all sky surveys. I find future<br/><br/>arrays with uniform (u,v) coverage and small spectral evolution of their response in the (u,v,f) cube can minimize foreground leakage while pursuing 21cm imaging.
Physics
Astronomy
21cm
Cosmic background radiation
early universe
Radio Astronomy
reionization
Cosmic background radiation
Cosmology
Techniques for the analysis and understanding of cosmic evolution