Quantum Optical Binding of Nanoscale Particles

Henning Rudolph; Uroš Delić; Klaus Hornberger; Benjamin A. Stickler

doi:arXiv.2412.03204

Quantum Optical Binding of Nanoscale Particles

Henning Rudolph, Uroš Delić, Klaus Hornberger, Benjamin A. Stickler

Quantum Optics, Quantum Nanophysics and Quantum Information

Publications: Contribution to journal › Article › Peer Reviewed

Abstract

Optical binding refers to the light-induced interaction between two or more objects illuminated by laser fields. The high tunability of the strength, sign, and reciprocity of this interaction renders it highly attractive for controlling nanoscale mechanical motion. Here, we discuss the quantum theory of optical binding and identify unique signatures of this interaction in the quantum regime. We show that these signatures are observable in near-future experiments with levitated nanoparticles. In addition, we prove the impossibility of entanglement induced by far-field optical binding in free space and identify strategies to circumvent this no-go theorem.

Original language	English
Article number	233603
Number of pages	6
Journal	Physical Review Letters
Volume	133
Issue number	23
DOIs	https://doi.org/arXiv.2412.03204 https://doi.org/10.1103/PhysRevLett.133.233603
Publication status	Published - 6 Dec 2024

Austrian Fields of Science 2012

103026 Quantum optics
103021 Optics

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arXiv.2412.03204Licence: Other
10.1103/PhysRevLett.133.233603

Cite this

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abstract = "Optical binding refers to the light-induced interaction between two or more objects illuminated by laser fields. The high tunability of the strength, sign, and reciprocity of this interaction renders it highly attractive for controlling nanoscale mechanical motion. Here, we discuss the quantum theory of optical binding and identify unique signatures of this interaction in the quantum regime. We show that these signatures are observable in near-future experiments with levitated nanoparticles. In addition, we prove the impossibility of entanglement induced by far-field optical binding in free space and identify strategies to circumvent this no-go theorem.",

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N2 - Optical binding refers to the light-induced interaction between two or more objects illuminated by laser fields. The high tunability of the strength, sign, and reciprocity of this interaction renders it highly attractive for controlling nanoscale mechanical motion. Here, we discuss the quantum theory of optical binding and identify unique signatures of this interaction in the quantum regime. We show that these signatures are observable in near-future experiments with levitated nanoparticles. In addition, we prove the impossibility of entanglement induced by far-field optical binding in free space and identify strategies to circumvent this no-go theorem.

AB - Optical binding refers to the light-induced interaction between two or more objects illuminated by laser fields. The high tunability of the strength, sign, and reciprocity of this interaction renders it highly attractive for controlling nanoscale mechanical motion. Here, we discuss the quantum theory of optical binding and identify unique signatures of this interaction in the quantum regime. We show that these signatures are observable in near-future experiments with levitated nanoparticles. In addition, we prove the impossibility of entanglement induced by far-field optical binding in free space and identify strategies to circumvent this no-go theorem.

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Quantum Optical Binding of Nanoscale Particles

Abstract

Austrian Fields of Science 2012

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Cavity mediated interactions between levitated particles

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Quantum Optical Binding of Nanoscale Particles

Abstract

Austrian Fields of Science 2012

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Cavity mediated interactions between levitated particles

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