Particle theory

Search for periodic neutrino emission from X-ray binaries

Journal of Instrumentation IOP Publishing 16:09 (2021) c09025

Sensitivity of a search for eV-scale sterile neutrinos with 8 years of IceCube DeepCore data

Journal of Instrumentation IOP Publishing 16:09 (2021) c09005

Starting track events in IceCube

Journal of Instrumentation IOP Publishing 16:09 (2021) c09015

Using convolutional neural networks to reconstruct energy of GeV scale IceCube neutrinos

Journal of Instrumentation IOP Publishing 16:09 (2021) c09019

Axion quasiparticles for axion dark matter detection

Journal of Cosmology and Astroparticle Physics IOP Publishing 2021:08 (2021) 066

Authors:

Jan Schütte-Engel, David JE Marsh, Alexander J Millar, Akihiko Sekine, Francesca Chadha-Day, Sebastian Hoof, Mazhar N Ali, Kin Chung Fong, Edward Hardy, Libor Šmejkal

Abstract:

It has been suggested that certain antiferromagnetic topological insulators contain axion quasiparticles (AQs), and that such materials could be used to detect axion dark matter (DM). The AQ is a longitudinal antiferromagnetic spin fluctuation coupled to the electromagnetic Chern-Simons term, which, in the presence of an applied magnetic field, leads to mass mixing between the AQ and the electric field. The electromagnetic boundary conditions and transmission and reflection coefficients are computed. A model for including losses into this system is presented, and the resulting linewidth is computed. It is shown how transmission spectroscopy can be used to measure the resonant frequencies and damping coefficients of the material, and demonstrate conclusively the existence of the AQ. The dispersion relation and boundary conditions permit resonant conversion of axion DM into THz photons in a material volume that is independent of the resonant frequency, which is tuneable via an applied magnetic field. A parameter study for axion DM detection is performed, computing boost amplitudes and bandwidths using realistic material properties including loss. The proposal could allow for detection of axion DM in the mass range between 1 and 10 meV using current and near future technology.