Implications of a Scalar Dark Force for Terrestrial Experiments

Feb, 2009
46 pages
Published in:
  • Phys.Rev.D 81 (2010) 063507
e-Print:

Citations per year

200920132017202120240123456
Abstract: (arXiv)
A long range Weak Equivalence Principle (WEP) violating force between Dark Matter (DM) particles, mediated by an ultralight scalar, is tightly constrained by galactic dynamics and large scale structure formation. We examine the implications of such a 'dark force' for several terrestrial experiments, including Eotvos tests of the WEP, direct-detection DM searches, and collider studies. The presence of a dark force implies a non-vanishing effect in Eotvos tests that could be probed by current and future experiments depending on the DM model. For scalar singlet DM scenarios, a dark force of astrophysically relevant magnitude is ruled out in large regions of parameter space by the DM relic density and WEP constraints. WEP tests also imply constraints on the Higgs-exchange contributions to the spin-independent (SI) DM-nucleus direct detection cross-section. For WIMP scenarios, these considerations constrain Higgs-exchange contributions to the SI cross-section to be subleading compared to gauge-boson mediated contributions. In multicomponent DM scenarios, a dark force would preclude large shifts in the rate for Higgs decay to two photons associated with DM-multiplet loops that might otherwise lead to measurable deviations at the LHC or a future linear collider. The combination of observations from galactic dynamics, large scale structure formation, Eotvos experiments, DM-direct-detection experiments, and colliders can further constrain the size of new long range forces in the dark sector.
Note:
  • 46 pages, 12 figures
  • dark matter: density
  • force: long-range
  • violation: equivalence principle
  • singlet: scalar
  • coupling: scalar
  • standard model
  • galaxy: formation
  • WIMP nucleon: elastic scattering
  • Higgs particle: exchange
  • parameter space