Gravitational Focusing of Wave Dark Matter

TL;DR

This paper explores how wave-like light bosonic dark matter is affected by gravitational focusing from the Sun, revealing unique signatures and potential experimental implications for local dark matter detection.

Contribution

It develops a formalism to analyze gravitational focusing of wave dark matter, highlighting distinctive density and spectral patterns, and compares wave and particle dark matter behaviors.

Findings

Gravitational focusing causes a few percent density enhancement for relaxed halos.

Dark matter substructures can produce larger focusing effects.

Wave nature leads to unique spectral signatures when de Broglie wavelength is comparable to system size.

Abstract

A massive astrophysical object deforms a local distribution of dark matter, resulting in a local overdensity of dark matter. This phenomenon is often referred to as gravitational focusing. In the solar system, the gravitational focusing due to the Sun induces modulations of dark matter signals on terrestrial experiments. We consider the gravitational focusing of a light bosonic dark matter with a mass of less than about 10 eV. The wave nature of such dark matter candidates leads to unique signatures both in the local overdensity and in the spectrum, both of which can be experimentally relevant. We provide a formalism that captures both the gravitational focusing and the stochasticity of wave dark matter, paying particular attention to the similarity and difference to particle dark matter. Distinctive patterns in the density contrast and spectrum are observed when the de Broglie wavelength of dark matter becomes comparable or less than the size of the system and/or when the velocity dispersion of dark matter is sufficiently small. While gravitational focusing effects generally remain at a few percent level for a relaxed halo dark matter component, they could be much larger for dark matter substructures. With a few well-motivated dark matter substructures, we investigate how each substructure responds to the gravitational potential of the Sun. The limit at which wave dark matter behaves similar to particle dark matter is also discussed.