Abstract
We explore the prospects for direct detection of dark energy by current and upcoming terrestrial dark matter direct detection experiments. If dark energy is driven by a new light degree of freedom coupled to matter and photons then dark energy quanta are predicted to be produced in the Sun. These quanta free-stream towards Earth where they can interact with Standard Model particles in the detection chambers of direct detection experiments, presenting the possibility that these experiments could be used to test dark energy. Screening mechanisms, which suppress fifth forces associated with new light particles, and are a necessary feature of many dark energy models, prevent production processes from occurring in the core of the Sun, and similarly, in the cores of red giant, horizontal branch, and white dwarf stars. Instead, the coupling of dark energy to photons leads to production in the strong magnetic field of the solar tachocline via a mechanism analogous to the Primakoff process. This then allows for detectable signals on Earth while evading the strong constraints that would typically result from stellar probes of new light particles. As an example, we examine whether the electron recoil excess recently reported by the XENON1T collaboration can be explained by chameleon-screened dark energy, and find that such a model is preferred over the background-only hypothesis at the $2.0\sigma$ level, in a large range of parameter space not excluded by stellar (or other) probes. This raises the tantalizing possibility that XENON1T may have achieved the first direct detection of dark energy. Finally, we study the prospects for confirming this scenario using planned future detectors such as XENONnT, PandaX-4T, and LUX-ZEPLIN.
Highlights
More than two decades after the discovery that the expansion of the Universe is accelerating [1,2], the nature of the dark energy (DE) component driving this phenomenon and making up ∼70% of the energy budget of the Universe remains a mystery [3,4,5,6,7]
The purpose of this paper is to broaden the scope of new physics accessible to terrestrial dark matter (DM) direct detection experiments by exploring their potential to detect DE quanta produced in the Sun, and to open up a new frontier for the direct detection of dark energy
Our aim has been to broaden the scope of new physics accessible to terrestrial dark matter (DM) direct detection experiments by investigating the intriguing possibility that these instruments may be able to detect DE quanta via their couplings to matter
Summary
More than two decades after the discovery that the expansion of the Universe is accelerating [1,2], the nature of the dark energy (DE) component driving this phenomenon and making up ∼70% of the energy budget of the Universe remains a mystery [3,4,5,6,7]. What is perhaps the simplest theoretical DE candidate, a cosmological constant (CC) resulting from the collective zero-point energy of quantum fields, suffers from a severe disagreement between its theoretical value suggested from quantum field theory considerations, and the tiny value inferred from cosmological observations [8,9,10]. Rubin Observatory Legacy Survey of Space and Time [18], and the Nancy Grace Roman Space Telescope [19]
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