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Quantum gravitational decoherence from fluctuating minimal length and deformation parameter at the Planck scale

Luciano Petruzziello, Fabrizio Illuminati

2021Nature Communications105 citationsDOIOpen Access PDF

Abstract

Schemes of gravitationally induced decoherence are being actively investigated as possible mechanisms for the quantum-to-classical transition. Here, we introduce a decoherence process due to quantum gravity effects. We assume a foamy quantum spacetime with a fluctuating minimal length coinciding on average with the Planck scale. Considering deformed canonical commutation relations with a fluctuating deformation parameter, we derive a Lindblad master equation that yields localization in energy space and decoherence times consistent with the currently available observational evidence. Compared to other schemes of gravitational decoherence, we find that the decoherence rate predicted by our model is extremal, being minimal in the deep quantum regime below the Planck scale and maximal in the mesoscopic regime beyond it. We discuss possible experimental tests of our model based on cavity optomechanics setups with ultracold massive molecular oscillators and we provide preliminary estimates on the values of the physical parameters needed for actual laboratory implementations.

Topics & Concepts

Quantum decoherencePhysicsPlanck lengthMesoscopic physicsQuantumPlanckClassical mechanicsQuantum mechanicsGravitationQuantum dissipationPlanck scaleQuantum gravityPlanck massMaster equationLength scalePlanck energyQuantum fluctuationOptomechanicsStatistical physicsScale (ratio)Quantum metrologyParameter spaceDeformation (meteorology)SpacetimeOpen quantum systemQuantum electrodynamicsQuantum processQuantum opticsNoncommutative and Quantum Gravity TheoriesQuantum Electrodynamics and Casimir EffectQuantum Mechanics and Applications
Quantum gravitational decoherence from fluctuating minimal length and deformation parameter at the Planck scale | Litcius