An ultralight pseudoscalar boson

Abstract

Using a fundamental discrete symmetry, ZN, we construct a two-axion model with the QCD axion solving the strong-CP problem, and an ultralight axion (ULA) with m ULA≈ 10-22 eV providing the dominant form of dark matter (DM). The ULA is light enough to be detectable in cosmology from its imprints on structure formation, and may resolve the small-scale problems of cold DM. The necessary relative DM abundances occur without fine tuning in constructions with decay constants f ULA 1017 GeV, and f QCD 1011 GeV. An example model achieving this has N=24, and we construct a range of other possibilities. We compute the ULA couplings to the Standard Model, and discuss prospects for direct detection. The QCD axion may be detectable in standard experiments through the E·B and GG couplings. In the simplest models, however, the ULA has identically zero coupling to both GG of QCD and E·B of electromagnetism due to vanishing electromagnetic and color anomalies. The ULA couples to fermions with strength g 1/f ULA. This coupling causes spin precession of nucleons and electrons with respect to the DM wind with period t. Current limits do not exclude the predicted coupling strength, and our model is within reach of the CASPEr-Wind experiment, using nuclear magnetic resonance.