Effective Field Theory of Dark Matter Direct Detection With Collective Excitations

TL;DR

This paper develops a comprehensive effective field theory framework for light dark matter detection via phonon and magnon excitations, identifying new response channels and applying it to various models, with implications for experimental searches.

Contribution

It generalizes previous models by including orbital and spin-orbit responses, providing a versatile framework and a publicly available code for calculating detection rates in diverse materials.

Findings

Couplings to nucleons and electron spins often dominate detection rates.

Exotic materials with orbital order are not necessary for strong detection sensitivity.

PhonoDark code enables rate calculations across various materials and models.

Abstract

We develop a framework for computing light dark matter direct detection rates through single phonon and magnon excitations via general effective operators. Our work generalizes previous calculations focused on spin-independent interactions involving the total nucleon and electron numbers $N$ (the usual route to excite phonons) and spin-dependent interactions involving the total electron spin $S$ (the usual route to excite magnons), leading us to identify new responses involving the orbital angular momenta $L$, as well as spin-orbit couplings $L\otimes S$ in the target. All four types of responses can excite phonons, while couplings to electron's $S$ and $L$ can also excite magnons. We apply the effective field theory approach to a set of well-motivated relativistic benchmark models, including (pseudo-)scalar mediated interactions, and models where dark matter interacts via a multipole moment, such as a dark electric dipole, magnetic dipole or anapole moment. We find that couplings to point-like degrees of freedom $N$ and $S$ often dominate dark matter detection rates, implying that exotic materials with orbital $L$ order or large spin-orbit couplings $L\otimes S$ are not necessary to have strong reach to a broad class of DM models. We highlight that phonon based crystal experiments in active R&D (such as SPICE) will probe light dark matter models well beyond those having a simple spin-independent interaction, including e.g. models with dipole and anapole interactions. Lastly, we make publicly available a code, PhonoDark, which computes single phonon production rates in a wide variety of materials with the effective field theory framework.