General Relativistic Decoherence with Applications to Dark Matter Detection
Itamar J. Allali, Mark P. Hertzberg
Abstract
Quantum mechanics allows for states in macroscopic superpositions, but they ordinarily undergo rapid decoherence due to interactions with their environment. A system that only interacts gravitationally, such as an arrangement of dark matter (DM), may exhibit slow decoherence. In this Letter, we compute the decoherence rate of a quantum object within general relativity, focusing on superposed metric oscillations; a rare quantum general relativistic result. For axion DM in a superposition of the field's phase, we find that DM in the Milky Way is robust against decoherence, while a spatial superposition is not. This novel phase behavior may impact direct detection experiments.
Topics & Concepts
Quantum decoherencePhysicsSuperposition principleAxionQuantum mechanicsQuantum dissipationQuantumClassical mechanicsDark matterParticle physicsDark Matter and Cosmic PhenomenaQuantum Mechanics and ApplicationsQuantum Electrodynamics and Casimir Effect