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Creating atom-nanoparticle quantum superpositions

Marko Toroš, Sougato Bose, P. F. Barker

2021Physical Review Research12 citationsDOIOpen Access PDF

Abstract

A nanoscale object evidenced in a nonclassical state of its center of mass will hugely extend the boundaries of quantum mechanics. To obtain a practical scheme for the same, we exploit a hitherto unexplored coupled system: an atom and a nanoparticle coupled by an optical field. We show how to control the center of mass of a large $\ensuremath{\sim}500$-nm nanoparticle using the internal state of the atom so as to create, as well as detect, nonclassical motional states of the nanoparticle. Specifically, we consider a setup based on a silica nanoparticle coupled to a cesium atom and discuss a protocol for preparing and verifying a Schr\"odinger-cat state of the nanoparticle that does not require cooling to the motional ground state. We show that the existence of the superposition can be revealed using the Earth's gravitational field using a method that is insensitive to the most common sources of decoherence and works for any initial state of the nanoparticle.

Topics & Concepts

Quantum decoherenceNanoparticleSuperposition principleQuantum superpositionAtom (system on chip)PhysicsGround stateQuantum stateField (mathematics)QuantumState (computer science)Quantum mechanicsNanotechnologyMaterials scienceComputer scienceMathematicsAlgorithmPure mathematicsEmbedded systemMechanical and Optical ResonatorsQuantum Mechanics and ApplicationsQuantum Information and Cryptography
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