The evolution of escaping ionizing radiation from galaxies and active galactic nuclei through cosmic time

Reionization is the phase transition of intergalactic atoms from being neutral to

becoming fully ionized. This process began ∼400 Myr after the Big Bang, when the first

stars and black holes began emitting ionizing radiation from stellar photospheres and

accretion disks. Reionization completed when all of the neutral matter between galaxies

became ionized ∼1 Gyr after the Big Bang, and the Universe became transparent as

it is today.

Characteristics of the galaxies that drove reionization are mostly unknown. The

physical mechanisms that create ionizing radiation inside these galaxies, and the

paths for this light to escape are even more unclear. To date, only a small fraction of

the numerous searches for this escaping light have been able to detect a faint signal

from distant galaxies, and no consensus on how Reionization was completed has been

established.

In this dissertation, I discuss the evolution of the atomic matter between galaxies

from its initially ionized state, to its current re-ionized state, potential sources of

re-ionizing energy, and the theoretical and observational status of the characteristics of

these sources. I also present new constraints on what fraction of the ionizing radiation

escapes from galaxies using Hubble Space Telescope UV imaging, theoretical models

of the stellar and accretion disk radiation, and models of the absorption of ionizing

radiation by the intergalactic medium.