Probing ultralight dark fields in cosmological and astrophysical systems

TL;DR

This paper develops a systematic effective field theory framework to study the interactions and dynamics of ultralight dark matter in astrophysical systems, aiding future detection efforts.

Contribution

It introduces a model-independent approach for constructing effective field theories of ultralight dark fields and explores their interactions in various astrophysical contexts.

Findings

Systematic method for effective field theory construction

Analysis of ultralight dark matter interactions with gravity and matter

Potential signatures in astrophysical phenomena

Abstract

Dark matter constitutes $26\%$ of the total energy in our universe, but its nature remains elusive. Among the assortment of viable dark matter candidates, particles and fields with masses lighter than $40 \mathrm{eV}$, called ultralight dark matter, stand out as particularly promising thanks to their feasible production mechanisms, consistency with current observations, and diverse and testable predictions. In light of ongoing and forthcoming experimental and observational efforts, it is important to advance the understanding of ultralight dark matter from theoretical and phenomenological perspectives: How does it interact with itself, ordinary matter, and gravity? What are some promising ways to detect it? In this thesis, we aim to explore the dynamics and interaction of ultralight dark matter and other astrophysically accessible hypothetical fields in a relatively model-independent way. Without making specific assumptions about their ultraviolet physics, we first demonstrate a systematic approach for constructing a classical effective field theory for both scalar and vector dark fields and discuss conditions for its validity. Then, we explore the interaction of ultralight dark fields, both gravitational and otherwise, within various contexts such as nontopological solitons, neutron stars, and gravitational waves.