Abstract
The dark photon is a massive hypothetical particle that interacts with the Standard Model by kinetically mixing with the visible photon. For small values of the mixing parameter, dark photons can evade cosmological bounds to be a viable dark matter candidate. Due to the similarities with the electromagnetic signals generated by axions, several bounds on dark photon signals are simply reinterpretations of historical bounds set by axion haloscopes. However, the dark photon has a property that the axion does not: an intrinsic polarisation. Due to the rotation of the Earth, accurately accounting for this polarisation is nontrivial, highly experiment-dependent, and depends upon assumptions about the dark photon's production mechanism. We show that if one does account for the DP polarisation, and the rotation of the Earth, an experiment's discovery reach can be enhanced by over an order of magnitude. We detail the strategies that would need to be taken to properly optimise a dark photon search. These include judiciously choosing the location and orientation of the experiment, as well as strategically timing any repeated measurements. Experiments located at $\pm$35$^\circ$ or $\pm$55$^\circ$ latitude, making three observations at different times of the sidereal day, can achieve a sensitivity that is fully optimised and insensitive to the dark photon's polarisation state, and hence its production mechanism. We also point out that several well-known searches for axions employ techniques for testing signals that preclude their ability to set exclusion limits on dark photons, and hence should not be reinterpreted as such.
Highlights
The hypothesis that galactic dark matter (DM) halos are comprised of a cold population of bosons is accumulating substantial interest in both theoretical and experimental circles [1,2,3]
We show that if one does account for the dark photon polarization, and the rotation of the Earth, an experiment’s discovery reach can be enhanced by over an order of magnitude
There are many interesting dark photon (DP) production mechanisms that can successfully produce the correct abundance of DM, several of them leading to some level of coherence in the polarization distribution of the relic DP field, possibly over the entire Universe
Summary
The hypothesis that galactic dark matter (DM) halos are comprised of a cold population of bosons is accumulating substantial interest in both theoretical and experimental circles [1,2,3]. While many haloscopes designed to search for axions are sensitive to DPs, there are few, if any, dedicated exclusion analyses made by their respective collaborations. Especially those designed to detect axions, are only sensitive to E fields aligning with one axis, this will make any DP interpretation of those experimental analyses strongly orientation and time dependent. We will derive a set of mathematical formulas to compute relevant quantities needed to account for the Earth’s rotation with respect to the DP These results take the form of conversion factors that quantify how much an exclusion limit is impacted by the range of possible angles between the DP polarization and the axis or plane that the experiment is sensitive to. All the figures created for this paper can be reproduced using the code available at https://github.com/cajohare/DarkPhotonCookbook with the exception of the DP constraint plots and their associated data which are available at https://cajohare.github.io/ AxionLimits
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