Bell correlations between light and vibration at ambient conditions

Velez, Santiago Tarrago; Sudhir, V.; Sangouard, Nicolas; Galland, Christophe

doi:10.1126/sciadv.abb0260

Cited by 13 publications

(3 citation statements)

References 53 publications

(69 reference statements)

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“…We estimate that about N ~ 10 10 randomly moving molecules occupy the focal volume. If we consider them individually, the Raman interaction can be modeled as a tensor product of N two-mode squeezing unitary operators acting on the vacuum state of the Stokes photon ( S ) and the vibration ( v ) 20 , 52 . Assuming the same Raman cross-section for all the molecules and uniform field intensity within the focal volume, and ignoring corrections from time-ordering of operators 55 , 56 as valid in the low-gain regime, the state of the system after a short interaction is where p ≃ 10 −2 in our experimental conditions (low gain, spontaneous regime).…”

Section: Discussionmentioning

confidence: 99%

“…Following a pioneering work by I. Walmsley and coworkers in 2011 11 , more recent experiments have used time-correlated single photon counting to evidence non-classical intensity correlations between light fields interacting with the same phonon mode via Raman scattering, with potential applications in ultrafast quantum information processing [12][13][14][15][16][17] , novel forms of spectroscopy 18,19 , and the generation of non-classical states of light 20 . These experimental results have spurred further theoretical developments to understand how the Raman process leads to photonic correlations mediated by a phononic excitation [21][22][23][24] , how the experimental geometry impacts the photon statistics of the Stokes field 25 , and how the coupling of a Raman-active mode to a nanocavity modifies the dynamics of the system [26][27][28] .…”

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Measurement-induced collective vibrational quantum coherence under spontaneous Raman scattering in a liquid

et al. 2023

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Spontaneous vibrational Raman scattering is a ubiquitous form of light–matter interaction whose description necessitates quantization of the electromagnetic field. It is usually considered as an incoherent process because the scattered field lacks any predictable phase relationship with the incoming field. When probing an ensemble of molecules, the question therefore arises: What quantum state should be used to describe the molecular ensemble following spontaneous Stokes scattering? We experimentally address this question by measuring time-resolved Stokes–anti-Stokes two-photon coincidences on a molecular liquid consisting of several sub-ensembles with slightly different vibrational frequencies. When spontaneously scattered Stokes photons and subsequent anti-Stokes photons are detected into a single spatiotemporal mode, the observed dynamics is inconsistent with a statistical mixture of individually excited molecules. Instead, we show that the data are reproduced if Stokes–anti-Stokes correlations are mediated by a collective vibrational quantum, i.e. a coherent superposition of all molecules interacting with light. Our results demonstrate that the degree of coherence in the vibrational state of the liquid is not an intrinsic property of the material system, but rather depends on the optical excitation and detection geometry.

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Measurement-induced collective vibrational quantum coherence under spontaneous Raman scattering in a liquid

et al. 2023

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“…In a different approach, modulations on terahertz waves have been read out optically through a megahertz-frequency mechanical resonator ( 22 ). Molecular oscillators constitute a new frontier in cavity optomechanics ( 23 , 24 ) because they enable multi-terahertz resonant frequencies and room temperature quantum coherent operation ( 25 ). Moreover, they can be coupled to plasmonic nanocavities with deep-subwavelength mode volumes, thereby enabling optomechanical coupling rates in excess of 1 THz ( 26 ).…”

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Continuous-wave frequency upconversion with a molecular optomechanical nanocavity

Chen

Roelli

et al. 2021

Science

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Optomechanical upconversion Molecules have rich signatures in their spectra at infrared wavelengths and are typically accessed with dedicated spectroscopic instrumentation. Chen et al . and Xomalis et al . report optomechanical frequency upconversion from the mid-infrared to the visible domain using molecular vibrations coupled to a plasmonic nanocavity at ambient conditions (see the Perspective by Gordon). Using different nanoantenna designs, one with a nanoparticle-on-resonator and the other with nanoparticle-in-groove, both approaches show the ability to upconvert the mid-infrared vibrations of the molecules in the nanocavity to visible light wavelengths. The effect could be used to simplify infrared spectroscopy, possibly with single-molecule sensitivity. —ISO

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Room-temperature phonon-coupled single-photon emission in hexagonal boron nitride

Lai,

Tan,

Song

et al. 2024

Sci. China Phys. Mech. Astron.

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Bell correlations between light and vibration at ambient conditions

Cited by 13 publications

References 53 publications

Measurement-induced collective vibrational quantum coherence under spontaneous Raman scattering in a liquid

Measurement-induced collective vibrational quantum coherence under spontaneous Raman scattering in a liquid

Continuous-wave frequency upconversion with a molecular optomechanical nanocavity

Room-temperature phonon-coupled single-photon emission in hexagonal boron nitride

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