Precise cosmological analysis of Type Ia supernovae: the Hubble constant and dark energy
Abstract
The field of physical cosmology has advanced greatly in the last
few decades. In this time, a holistic `concordance' model of our
Universe has been pieced together: an isotropic and homogeneous
Universe which started very small, went through a brief
inflationary period, and obeys General Relativity. Approximately
a third of its energy content can be attributed to matter (mostly
cold dark matter, with some baryonic), and the remainder to
`dark' energy, which appears to be a cosmological constant, tied
to spacetime itself. Together, these components are referred to
as the LambdaCDM model.
Type Ia supernovae (SNe Ia) have been instrumental in reaching
this understanding, playing a pivotal role in the late 1990s by
signalling the Universe's accelerated expansion. Since then, SNe
Ia and the other probes (baryon acoustic oscillations, weak
lensing, and clustering) have been employed to improve
constraints on the quantities that parametrise LambdaCDM, and the
equation-of-state parameter w for dark energy. These efforts have
converged in the Dark Energy Survey (2013-2018), which
coordinates these probes. The paradigm for cosmology now is to
diminish systematic errors to obtain precise measurements of
cosmological parameters through observations far into the distant
past.
More locally, the Hubble constant H_0 determines the expansion
rate of the Universe at present; this normalises its distance
scale. In the past several years, the precise value of H_0 has
come into contention, with a significant discrepancy between
results determined from a local distance ladder (with SNe Ia at
the top), and those inferred from observations of the early
Universe assuming the cosmological models that drive its
expansion history. Taken at face value, this discrepancy could
signal systematic errors in either measurement, or inaccurate
assumptions about the model.
The efforts in this thesis use SNe Ia to address questions at
both ends of the Universe's expansion history - the Hubble
constant locally, and dark energy at higher redshifts - using the
current best methods to account for the statistical and
systematic terms which affect supernovae. These methods, were
developed by the Supernova Legacy Survey (SNLS) and subsequent
Joint Lightcurve Analysis (JLA), rely on covariance matrices to
encapsulate correlated uncertainties in all lightcurve
parameters, which are then propagated through probabilistic
Bayesian parameter estimation methods to uncertainties in
cosmological parameters.
In the works contained within this thesis, I have developed a
framework for performing precise cosmological analysis of SNe Ia
samples, including using covariance matrices to quantify
systematic terms. I have applied to the aforementioned pertinent
questions: the value of the Hubble constant and the nature of
dark energy, using the datasets in SH0ES (Riess et al. 2011) and
intermediate Dark Energy Survey supernova data.
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