Self-Gravitating Scalar Field Configurations, Ultra Light Dark Matter and Galactic Scale Observations

Abstract

In this thesis, we investigate the possibility that dark matter consists of ultra light spin-zero particles with mass m 10-22\ eV. We focus on the role of self-interactions, assuming all other non-gravitational couplings to Standard Model particles are negligible. Such ultra light dark matter (ULDM) is expected to form stable self-gravitating scalar field configurations (solitons), whose properties depend on the particle mass and self-coupling λ. Using solutions of the Gross-Pitaevskii-Poisson equations, we explore how galactic-scale observations can constrain m and λ. We show that observational upper limits on the mass enclosed in central galactic regions can probe both attractive and repulsive self-interactions with strengths λ 10-96 - 10-95. We further demonstrate that self-interactions can allow ULDM to describe observed rotation curves as well as satisfy an empirical soliton-halo mass relation in low surface brightness galaxies for m 10-22\ eV and λ 10-90. We also study tidal effects in satellite dwarf galaxies and find that attractive self-interactions can extend their lifetimes over cosmological timescales, allowing ULDM to evade recent constraints derived for the non-interacting case. Finally, we explore machine learning based inference of dark matter and baryonic parameters from galaxy rotation curves, showing that neural networks can recover parameters consistent with observations.

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