The puzzles of dark matter searches

TL;DR

This paper explores a novel dark matter candidate, O-helium, which could explain DAMA's positive signals while remaining undetected in other experiments, through nuclear interactions and specific binding energies.

Contribution

It introduces a new dark matter model involving O-helium atoms and analyzes their nuclear interactions to explain experimental discrepancies.

Findings

OHe can bind with sodium and iodine nuclei producing keV energy releases.

The model explains DAMA signals without contradicting null results from other detectors.

Predicted binding energies vary with detector material, affecting detection prospects.

Abstract

Positive results of dark matter searches in DAMA/NaI and DAMA/LIBRA experiments, being put together with negative results of other groups, can imply nontrivial particle physics solutions for cosmological dark matter. Stable particles with charge -2 bind with primordial helium in O-helium "atoms" (OHe), representing a specific Warmer than Cold nuclear-interacting form of dark matter. Slowed down in the terrestrial matter, OHe is elusive for direct methods of underground Dark matter detection like those used in CDMS experiment, but its reactions with nuclei can lead to annual variations of energy release in the interval of energy 2-6 keV in DAMA/NaI and DAMA/LIBRA experiments. Schrodinger equation for system of nucleus and OHe is solved for spherically symmetrical potential well, formed by the Yukawa tail of nuclear scalar isoscalar attraction potential, acting on He beyond the nucleus, and dipole Coulomb repulsion between the nucleus and OHe at distances from the nuclear surface, smaller than the size of OHe. The window of parameters of this potential is found, at which the sodium and/or iodine nuclei have a few keV binding energy with OHe. At nuclear parameters, reproducing DAMA results, the energy release predicted for detectors with chemical content other than NaI differ in the most cases from the one in DAMA detector. In particular, it is shown that in the case of CDMS the energy of OHe-germanium bound state is beyond the range of 2-6 keV and its formation should not lead to ionization in the energy interval of DAMA signal. (abridged)