Photon number statistics uncover the fluctuations in non-equilibrium lattice dynamics

Martina Esposito; Kelvin Titimbo; Klaus Zimmermann; Francesca Giusti; Francesco Randi; Davide Boschetto; Fulvio Parmigiani; Roberto Floreanini; Fabio Benatti; Daniele Fausti

doi:10.1038/ncomms10249

Photon number statistics uncover the fluctuations in non-equilibrium lattice dynamics

Martina Esposito
, Kelvin Titimbo
, Klaus Zimmermann
, Francesca Giusti
, Francesco Randi
, Davide Boschetto
, Fulvio Parmigiani
, Roberto Floreanini
, Fabio Benatti
, Daniele Fausti

Research output: Contribution to journal › Article › peer-review

Abstract

Fluctuations of the atomic positions are at the core of a large class of unusual material properties ranging from quantum para-electricity to high temperature superconductivity. Their measurement in solids is the subject of an intense scientific debate focused on seeking a methodology capable of establishing a direct link between the variance of the atomic displacements and experimentally measurable observables. Here we address this issue by means of non-equilibrium optical experiments performed in shot-noise-limited regime. The variance of the time-dependent atomic positions and momenta is directly mapped into the quantum fluctuations of the photon number of the scattered probing light. A fully quantum description of the non-linear interaction between photonic and phononic fields is benchmarked by unveiling the squeezing of thermal phonons in α-quartz.

Original language	English
Article number	10249
Journal	Nature Communications
Volume	6
DOIs	https://doi.org/10.1038/ncomms10249
Publication status	Published - 22 Dec 2015
Externally published	Yes

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10.1038/ncomms10249

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title = "Photon number statistics uncover the fluctuations in non-equilibrium lattice dynamics",

abstract = "Fluctuations of the atomic positions are at the core of a large class of unusual material properties ranging from quantum para-electricity to high temperature superconductivity. Their measurement in solids is the subject of an intense scientific debate focused on seeking a methodology capable of establishing a direct link between the variance of the atomic displacements and experimentally measurable observables. Here we address this issue by means of non-equilibrium optical experiments performed in shot-noise-limited regime. The variance of the time-dependent atomic positions and momenta is directly mapped into the quantum fluctuations of the photon number of the scattered probing light. A fully quantum description of the non-linear interaction between photonic and phononic fields is benchmarked by unveiling the squeezing of thermal phonons in α-quartz.",

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AU - Esposito, Martina

AU - Titimbo, Kelvin

AU - Zimmermann, Klaus

AU - Giusti, Francesca

AU - Randi, Francesco

AU - Boschetto, Davide

AU - Parmigiani, Fulvio

AU - Floreanini, Roberto

AU - Benatti, Fabio

AU - Fausti, Daniele

PY - 2015/12/22

Y1 - 2015/12/22

N2 - Fluctuations of the atomic positions are at the core of a large class of unusual material properties ranging from quantum para-electricity to high temperature superconductivity. Their measurement in solids is the subject of an intense scientific debate focused on seeking a methodology capable of establishing a direct link between the variance of the atomic displacements and experimentally measurable observables. Here we address this issue by means of non-equilibrium optical experiments performed in shot-noise-limited regime. The variance of the time-dependent atomic positions and momenta is directly mapped into the quantum fluctuations of the photon number of the scattered probing light. A fully quantum description of the non-linear interaction between photonic and phononic fields is benchmarked by unveiling the squeezing of thermal phonons in α-quartz.

AB - Fluctuations of the atomic positions are at the core of a large class of unusual material properties ranging from quantum para-electricity to high temperature superconductivity. Their measurement in solids is the subject of an intense scientific debate focused on seeking a methodology capable of establishing a direct link between the variance of the atomic displacements and experimentally measurable observables. Here we address this issue by means of non-equilibrium optical experiments performed in shot-noise-limited regime. The variance of the time-dependent atomic positions and momenta is directly mapped into the quantum fluctuations of the photon number of the scattered probing light. A fully quantum description of the non-linear interaction between photonic and phononic fields is benchmarked by unveiling the squeezing of thermal phonons in α-quartz.

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DO - 10.1038/ncomms10249

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SN - 2041-1723

VL - 6

JO - Nature Communications

JF - Nature Communications

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ER -

Photon number statistics uncover the fluctuations in non-equilibrium lattice dynamics

Abstract

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