Astrophysical Frontiers: The Indirect Detection of Dark Matter & the Analysis of Gamma-ray Binary Systems

Abstract

This thesis is divided into two parts reflecting the two different fields of work presented within. The first half is dedicated to studies relating to indirect dark matter detection, while the second half details work undertaken in the very-high energy astronomy domain, specifically on the observations of gamma-ray binaries. The phenomenon of unseen mass in the Universe is as all-pervading as it is mysterious. The plethora of evidence in support of this conclusion spans both the baryonic and non-baryonic sectors, and the fingerprints of this unseen anomaly are detected through both direct and indirect methods making it a fundamental and ubiquitous part of the Universe. This "dark matter" remains one of the greatest challenges to modern cosmological models and to our understanding of the Universe. While many theories regarding its nature exist, it is as yet undetected and the identification of dark matter (composing 85% of the visible Universe) remains a very active field of research. Indirect detection of dark matter is a method that aims to infer the presence and properties of dark matter through the observation of secondary particles (mostly photons) resulting from dark matter interactions. In many dark matter models, secondary particles are produced through dark matter’s decay, annihilation, or other interactions with standard model particles. In dark matter-dominated astrophysical objects, these secondary particles would form an excess on top of the known astrophysical populations. This excess can be probed for using modern X-ray and gamma-ray telescopes, allowing for their distinction and association with dark matter. In most cases, the flux of these secondary particles would allow for the inference of dark matter and for the derivation of its properties. A lack of dark matter-associated flux detected by an instrument allows one to place limits on a given dark matter candidate particle’s properties. This work, in part, focuses on the field of indirect dark matter detection, specifically on the search for dark matter in astrophysical objects and the capacity of upcoming missions to fulfil this task. As part of this, the results of an annihilating dark matter search with Fermi-LAT in nearby galaxy clusters are presented. Moreover, studies into the potential of the upcoming THESEUS and eXTP missions in the detection of well-motivated decaying dark matter models are detailed. Gamma-ray Emitting Binary (GREB) systems are a category of high-mass binaries with unique and variable non-thermal emission, even between objects within the class. They are categorised as systems containing a massive young star and a compact object, whose energy spectra peak at above 1 MeV (but typically at E ≳ 100 MeV). These spectra, however, often extend to extremely high energies (E ≳ 10 TeV). The physical mechanisms for the production of this emission are not well established, making GREBs exciting and novel objects for study. The second part of this thesis focuses on the study of GREBs and, specifically, on the system of PSR B1259-63. This system is comprised of a pulsar in a highly eccentric 3.4 year orbit around the O9.5Ve star LS 2883 and is known to emit a range of non-thermal radiation from radio to Very-high-energy (VHE) gamma rays. The bulk of this non-thermal emission occurs around the periastron and is thought to be connected to the orientation of the star’s decretion disc of gas and dust to the orbital plane of the pulsar. This orientation means the pulsar crosses the disc ∼ 16 days before and after the periastron. With the exception of the GeV energy band, in which intra-periastron variability has been observed, the emission from the source across the wavelengths follows a similar form between periastron passages. However, the 2021 periastron saw a plethora of previously unseen and interesting behaviours in the system across different wavelengths. This thesis will detail the work undertaken to analyse and the results of the VHE data taken on the system, by the H.E.S.S. array during the 2021 periastron.