Novel Constraints on Spin-Dependent Light Dark Matter Scattering

Abstract

We explore the sensitivity of the SNO experiment to light dark matter particles with spin-dependent interactions with nucleons. We show that the pair-production of MeV scale dark matter is possible in heavy water (CANDU) reactors via D(n,)3 He, and calculate the expected rate within the simplest models of -nucleon interactions. %Heavy water nuclear reactors serve as an excellent production method for spin-dependent dark matter. Owing to a sizable Q-value for this reaction, a large fraction of DM particles produced this way are above the threshold for deuteron disintegration, D(,)np, which adds to the SNO neutral current signal. Evaluating the CANDU-to-SNO scheme for the production and detection of DM, we derive novel constraints for the -nucleon spin-dependent cross sections, showing that cross sections above σ p 10-33\, cm2 are generally excluded if m ≤1.5\,MeV. An isospin-mirror reaction will occur in the Sun, and for the kinematically allowed region it excludes a portion of parameter space with cross sections on the order 10-37\, cm2. We also evaluate the potential sensitivity of small ``near" detectors placed in close proximity to a CANDU reactor to search for a coherent nuclear recoil, finding subdominant sensitivity.