Dark Sector Effective Field Theory

TL;DR

This paper develops a comprehensive effective field theory framework for light dark particles interacting with the Standard Model, classifies operators up to dimension 7, and applies it to explain neutron lifetime anomalies and dark matter constraints.

Contribution

It introduces the dark sector effective field theory (DSEFT), classifies interaction operators, and applies the framework to neutron decay anomalies and dark matter phenomenology.

Findings

DSEFT covers six interaction categories with operators up to dimension 7.

Neutron dark decay modes can explain the lifetime anomaly.

Models are consistent with Super-Kamiokande dark matter constraints.

Abstract

We introduce the effective field theory of two different light dark particles interacting with the standard model (SM) light states in a single vertex, termed dark sector effective field theory (DSEFT). We focus on the new light particles with spin up to 1 and being real in essence, namely, new real scalars $\phi$ and $S$, Majorana fermions $\chi$ and $\psi$, and real vectors $X_\mu$ and $V_\mu$. In the framework of low energy effective field theory with QED and QCD symmetry, the DSEFT can be classified into six categories, including the scalar-scalar-SM ($\phi S$-SM), fermion-fermion-SM ($\chi\psi$-SM), vector-vector-SM ($X V$-SM), scalar-fermion-SM ($\phi \chi$-SM), scalar-vector-SM ($\phi X$-SM), and fermion-vector-SM ($\chi X$-SM) cases. For each case, we construct the effective operator basis up to canonical dimension 7, which will cover most interesting phenomenology at low energy. As a phenomenological example, we investigate the longstanding neutron lifetime anomaly through the neutron dark decay modes $n \to \chi \phi \text{ or } \chi X$ from the effective interactions in the fermion-scalar-SM or fermion-vector-SM case. When treating the light fermion as a dark matter candidate, we also explore the constraints from DM-neutron annihilation signal at Super-Kamiokande. We find the neutron dark decay in each scenario can accommodate the anomaly, at the same time, without contradicting with the Super-Kamiokande limit.