Prospects for direct detection of dark matter in an effective theory approach

TL;DR

This paper evaluates the potential for future ton-scale detectors to directly detect dark matter within a comprehensive 11-dimensional effective theory, analyzing synthetic data to assess parameter reconstruction and detection prospects.

Contribution

It introduces a detailed analysis of dark matter detection prospects using an 11-dimensional effective theory, including methods to identify interaction types directly from data.

Findings

Identification of 5 scenarios with simultaneous dark matter mass and interaction type reconstruction.

Demonstration of the importance of extracting interaction type directly from data.

Assessment of detection prospects across 27 benchmark points.

Abstract

We perform the first comprehensive analysis of the prospects for direct detection of dark matter with future ton-scale detectors in the general 11-dimensional effective theory of isoscalar dark matter-nucleon interactions mediated by a heavy spin-1 or spin-0 particle. The theory includes 8 momentum and velocity dependent dark matter-nucleon interaction operators, besides the familiar spin-independent and spin-dependent operators. From a variegated sample of 27 benchmark points selected in the parameter space of the theory, we simulate independent sets of synthetic data for ton-scale Germanium and Xenon detectors. From the synthetic data, we then extract the marginal posterior probability density functions and the profile likelihoods of the model parameters. The associated Bayesian credible regions and frequentist confidence intervals allow us to assess the prospects for direct detection of dark matter at the 27 benchmark points. First, we analyze the data assuming the knowledge of the correct dark matter nucleon-interaction type, as it is commonly done for the familiar spin-independent and spin-dependent interactions. Then, we analyze the simulations extracting the dark matter-nucleon interaction type from the data directly, in contrast to standard analyses. This second approach requires an extensive exploration of the full 11-dimensional parameter space of the dark matter-nucleon effective theory. Interestingly, we identify 5 scenarios where the dark matter mass and the dark matter-nucleon interaction type can be reconstructed from the data simultaneously. We stress the importance of extracting the dark matter nucleon-interaction type from the data directly, discussing the main challenges found addressing this complex 11-dimensional problem.