79 results on '"Dantan, Aurelien"'
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2. Narrow-linewidth Fano microcavities with resonant subwavelength grating mirror
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Mitra, Trishala, Singh, Gurpreet, Darki, Ali Akbar, Madsen, Søren Peder, and Dantan, Aurélien
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Physics - Optics - Abstract
We report on the theoretical and experimental investigations of optical microcavities consisting in the plane-plane arrangement of a broadband high-reflectivity mirror and a suspended one-dimensional grating mirror possessing a high-quality factor Fano resonance. By varying the length of these cavities from the millimeter to the few-micron range, we observe at short lengths the reduction of the spectral linewidth predicted to occur for such a Fano cavity as compared to a conventional broadband mirror cavity with the same length and internal losses. Such narrow linewidth and small modevolume microcavities with high-mechanical quality ultrathin mirrors will be attractive for a wide range of applications within optomechanics and sensing.
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- 2024
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3. Squeeze film absolute pressure sensors with sub-millipascal sensitivity
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Salimi, Mohsen, Nielsen, Robin V., Pedersen, Henrik B., and Dantan, Aurélien
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Physics - Applied Physics - Abstract
We report on the realization of ultrasensitive absolute pressure sensors based on silicon nitride membrane sandwiches. These sandwiches consist in a pair of highly-pretensioned, ultrathin (50 nm), large area (0.25 mm2) films, suspended parallel to each other and forming an ultrashort (500 nm), open cavity. The compression of a gas in this cavity leads to a strong squeeze film force, resulting in an increase in the membrane mechanical resonance frequencies which is directly proportional to the absolute gas pressure. These sandwiches show a record high responsitivity of >300 Hz/Pa in terms of squeeze film-induced frequency shift, which, combined with high quality factor mechanical resonances (Q>10^6), allows for bringing the sensitivity of absolute squeeze film pressure sensors down to the sub-millipascal level.
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- 2023
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4. Mechanical investigations of free-standing SiN membranes patterned with one-dimensional photonic crystal structures
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Darki, Ali A., Nielsen, Robin V., Nygaard, Jens V., and Dantan, Aurélien
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Physics - Applied Physics ,Physics - Optics - Abstract
A detailed investigation of the structural and vibrational properties of various prestressed silicon nitride membranes patterned with one-dimensional photonic crystal structures is presented. The tensile stress-related deformation of the structure in the vicinity of the patterned area is determined by Atomic Force Microscopy scans, while the resonance frequencies and quality factors of the out-of-plane membrane vibrations are measured using optical interferometry. We show that these noninvasive measurements, combined with results of finite element simulations, provide accurate knowledge on the tensile stress, the elasticity modulus and the density of these nanostructured thin films. The obtained results are interesting in two ways: first, they show that such highly reflective thin membranes already exploited in various photonics applications possess high-mechanical quality, which also makes them attractive for optomechanics and sensing applications. Second, they represent a nondestructive method to determine key material parameters which can be applicable to a broad range of fragile nanostructured thin films., Comment: 9 pages, 13 figures
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- 2022
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5. Squeeze film absolute pressure sensors with sub-millipascal sensitivity
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Salimi, Mohsen, Nielsen, Robin V., Pedersen, Henrik B., and Dantan, Aurélien
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- 2024
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6. Polarization-independent optical spatial differentiation with a doubly-resonant one-dimensional guided-mode grating
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Darki, Ali Akbar, Madsen, Søren Peder, and Dantan, Aurélien
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Physics - Optics - Abstract
We report on the design and experimental characterization of a suspended silicon nitride subwavelength grating possessing a polarization-independent guided-mode resonance at oblique incidence. At this resonant wavelength we observe that the transverse intensity profile of the transmitted beam is consistent with a first-order spatial differentiation of the incident beam profile in the direction of the grating periodicity, regardless of the incident light polarization. These observations are corroborated by full numerical simulations. The simple one-dimensional and symmetric design, combined with the thinness and excellent mechanical properties of these essentially loss-free dieletric films, is attractive for applications in optical processing, sensing and optomechanics.
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- 2021
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7. Collimation and finite-size effects in suspended resonant guided-mode gratings
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Toft-Vandborg, Christian, Parthenopoulos, Alexios, Darki, Ali Akbar, and Dantan, Aurélien
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Physics - Optics - Abstract
The optical transmission of resonant guided-mode gratings patterned on suspended silicon nitride thin films and illuminated at normal incidence with a Gaussian beam are investigated both experimentally and theoretically. Effects due to the beam focusing and its finite size are accounted for by a phenomenological coupled mode model whose predictions are found to be in very good agreement with the experimentally measured spectra for various grating structures and beam sizes, and which allow for a detailed analysis of the respective magnitude of these effects. These results are highly relevant for the design and optimization of such suspended structured films which are widely used for photonics, sensing and optomechanics applications., Comment: 13 pages, 13 figures
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- 2021
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8. Profilometry and stress analysis of suspended nanostructured thin films
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Darki, Ali Akbar, Parthenopoulos, Alexios, Nygaard, Jens Vinge, and Dantan, Aurélien
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Condensed Matter - Mesoscale and Nanoscale Physics - Abstract
The profile of suspended silicon nitride thin films patterned with one-dimensional subwavelength grating structures is investigated using Atomic Force Microscopy. We first show that the results of the profilometry can be used as input to Rigorous Coupled Wave Analysis simulations to predict the transmission spectrum of the gratings under illumination by monochromatic light at normal incidence and compare the results of the simulations with experiments. Secondly, we observe sharp vertical deflections of the films at the boundaries of the patterned area due to local modifications of the tensile stress during the patterning process. These deflections are experimentally observed for various grating structures and investigated on the basis of a simple analytical model as well as finite element method simulations.
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- 2020
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9. Optical spatial differentiation with suspended subwavelength gratings
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Parthenopoulos, Alexios, Darki, Ali Akbar, Jeppesen, Bjarke R., and Dantan, Aurélien
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Physics - Optics - Abstract
We demonstrate first- and second-order spatial differentiation of an optical beam transverse profile using thin suspended subwavelength gratings. Highly reflective one-dimensional gratings are patterned on suspended 200 nm-thick silicon nitride membranes using Electron Beam Lithography and plasma etching. The optical transmission of these gratings, designed for illumination with either TM or TE polarized light, are experimentally measured under normal and oblique incidence and found to be in excellent agreement with the predictions of an analytical coupled-mode model as well as Rigorous Coupled Wave Analysis numerical simulations. High quality first- and second-order spatial differentiation of a Gaussian beam are observed in transmission at oblique and normal incidence, respectively. Such easy-to-fabricate, ultrathin and loss-free optical components may be attractive for beam shaping and optical information processing and computing.
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- 2020
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10. Membrane sandwich squeeze film pressure sensors
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Dantan, Aurélien
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Physics - Applied Physics - Abstract
Squeeze film pressure sensors, exploiting the dynamical modification of the mechanical properties of oscillating elements due to the compression of a fluid in a small gap region, allow for direct and absolute pressure measurements. This tutorial article discusses the working principles of membrane sandwich squeeze film pressure sensors, i.e. sensors consisting in a parallel arrangement of two large area, ultrathin suspended films forming a few-micron gap and immersed in a fluid, and focuses on their operation in the free molecular flow regime. The effects of gas pressure on the vibrations of the membrane resonators and their coupled dynamics are discussed in general terms before recent experimental implementations using high tensile stress silicon nitride membranes are presented., Comment: 8 pages, 10 figures
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- 2020
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11. Stress-controlled frequency tuning and parametric amplification of the vibrations of coupled nanomembranes
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Naserbakht, Sepideh, Naesby, Andreas, and Dantan, Aurélien
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Physics - Applied Physics ,Condensed Matter - Mesoscale and Nanoscale Physics - Abstract
Noninvasive tuning of the mechanical resonance frequencies of suspended parallel nanomembranes in various monolithic arrays is achieved by piezoelectric control of their tensile stress. Parametric amplification of their thermal fluctuations is shown to be enhanced by the piezoelectric actuation and amplification factors of up to 20 dB in the sub-parametric oscillation threshold regime are observed.
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- 2019
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12. Squeeze film pressure sensors based on SiN membrane sandwiches
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Naserbakht, Sepideh and Dantan, Aurélien
- Subjects
Physics - Applied Physics ,Condensed Matter - Mesoscale and Nanoscale Physics - Abstract
We realize squeeze film pressure sensors using suspended, high mechanical quality silicon nitride membranes forming few-micron gap sandwiches. The effects of air pressure on the mechanical vibrations of the membranes are investigated in the range 10^-3-50 mbar and the intermembrane coupling induced by the gas is discussed in light of a squeeze film coupled-oscillator model. The high responsivity (several kHz/mbar) and the sub-pascal sensitivity of such simple pressure sensors are attractive for absolute and direct pressure measurements in rarefied air or high vacuum environments., Comment: 9 pages, 10 figures
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- 2019
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13. Electromechanics in vertically coupled nanomembranes
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Naserbakht, Sepideh, Naesby, Andreas, and Dantan, Aurélien
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Physics - Applied Physics ,Condensed Matter - Mesoscale and Nanoscale Physics - Abstract
We investigate the electromechanical actuation of a pair of suspended silicon nitride membranes forming a monolithic optomechanical array. By controlling the membrane resonators' tensile stress via a piezoelectrically controlled compressive force applied to the membrane chip we demonstrate noninvasive tuning of their mechanical mode spectrum, as well as strong intermode electromechanical coupling. Piezoelectric actuation is also shown to enhance the nonlinear response of the membranes, which is evidenced either by parametric amplification of the fundamental mode thermal fluctuations or by resonant driving of these modes into high amplitude states. Such an electro-optomechanical membrane array represents an attractive tunable and versatile platform for sensing, photonics and optomechanics applications., Comment: 6 pages, 5 figures
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- 2019
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14. Cavity Quantum Electrodynamics with Frequency-Dependent Reflectors
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Černotík, Ondřej, Dantan, Aurélien, and Genes, Claudiu
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Quantum Physics - Abstract
We present a general framework for cavity quantum electrodynamics with strongly frequency-dependent mirrors. The method is applicable to a variety of reflectors exhibiting sharp internal resonances as can be realized, for example, with photonic-crystal mirrors or with two-dimensional atomic arrays around subradiant points. Our approach is based on a modification of the standard input--output formalism to explicitly include the dynamics of the mirror's internal resonance. We show how to directly extract the interaction tuning parameters from the comparison with classical transfer matrix theory and how to treat the non-Markovian dynamics of the cavity field mode introduced by the mirror's internal resonance. As an application within optomechanics, we illustrate how a non-Markovian Fano cavity possessing a flexible photonic crystal mirror can provide both sideband resolution as well as strong heating suppression in optomechanical cooling. This approach, amenable to a wide range of systems, opens up possibilities for using hybrid frequency-dependent reflectors in cavity quantum electrodynamics for engineering novel forms of light-matter interactions.
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- 2019
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15. Suspended silicon nitride thin films with enhanced and electrically tunable reflectivity
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Nair, Bhagya, Naesby, Andreas, Jeppesen, Bjarke R., and Dantan, Aurélien
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Condensed Matter - Mesoscale and Nanoscale Physics - Abstract
We report on the realization of silicon nitride membranes with enhanced and electrically tunable reflectivity. A subwavelength one-dimensional grating is directly patterned on a suspended 200 nm-thick, high stress commercial film using electron beam lithography. A Fano resonance is observed in the transmission spectrum of TM polarized light impinging on the membrane at normal incidence, leading to an increase in its reflectivity from 10% to 78% at 937 nm. The observed spectrum is compared to the results of rigorous coupled wave analysis simulations based on measurements of the grating transverse profile through localized cuts of the suspended film with a Focused Ion Beam. By mounting the membrane chip on a ring piezoelectric transducer and applying a compressive force to the substrate we subsequently observe a shift of the transmission spectrum by 0.23 nm., Comment: 8 pages, 5 figures
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- 2018
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16. Controlling the potential landscape and normal modes of ion Coulomb crystals by a standing wave optical potential
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Lauprêtre, Thomas, Linnet, Rasmus B., Leroux, Ian D., Landa, Haggai, Dantan, Aurélien, and Drewsen, Michael
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Quantum Physics ,Physics - Atomic Physics - Abstract
Light-induced control of ions within small Coulomb crystals is investigated. By intense intracavity optical standing wave fields, subwavelength localization of individual ions is achieved for one-, two-, and three-dimensional crystals. Based on these findings, we illustrate numerically how the application of such optical potentials can be used to tailor the normal mode spectra and patterns of multi-dimensional Coulomb crystals. The results represent, among others, important steps towards controlling the crystalline structure of Coulomb crystals, investigating heat transfer processes at the quantum limit and quantum simulations of many-body systems., Comment: 6+12 pages. arXiv admin note: substantial text overlap with arXiv:1703.05089
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- 2018
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17. Interference effects in hybrid cavity optomechanics
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Černotík, Ondřej, Genes, Claudiu, and Dantan, Aurélien
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Quantum Physics - Abstract
Radiation pressure forces in cavity optomechanics allow for efficient cooling of vibrational modes of macroscopic mechanical resonators, the manipulation of their quantum states, as well as generation of optomechanical entanglement. The standard mechanism relies on the cavity photons directly modifying the state of the mechanical resonator. Hybrid cavity optomechanics provides an alternative approach by coupling mechanical objects to quantum emitters, either directly or indirectly via the common interaction with a cavity field mode. While many approaches exist, they typically share a simple effective description in terms of a single force acting on the mechanical resonator. More generally, one can study the interplay between various forces acting on the mechanical resonator in such hybrid mechanical devices. This interplay can lead to interference effects that may, for instance, improve cooling of the mechanical motion or lead to generation of entanglement between various parts of the hybrid device. Here, we provide such an example of a hybrid optomechanical system where an ensemble of quantum emitters is embedded into the mechanical resonator formed by a vibrating membrane. The interference between the radiation pressure force and the mechanically modulated Tavis--Cummings interaction leads to enhanced cooling dynamics in regimes in which neither force is efficient by itself. Our results pave the way towards engineering novel optomechanical interactions in hybrid optomechanical systems., Comment: 19 pages, 5 figures
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- 2018
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18. Microcavities with suspended subwavelength structured mirrors
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Naesby, Andreas and Dantan, Aurélien
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Physics - Optics ,Condensed Matter - Mesoscale and Nanoscale Physics - Abstract
We investigate the optical properties of microcavities with suspended subwavelength structured mirrors, such as high-contrast gratings or two-dimensional photonic crystals slabs, and focus in particular on the regime in which the microcavity free-spectral range is larger than the width of a Fano resonance of the highly reflecting structured mirror. In this unusual regime, the transmission spectrum of the microcavity essentially consists in a single mode, whose linewidth can be significantly narrower than both the Fano resonance linewidth and the linewidth of an equally short cavity without structured mirror. This generic interference effect---occuring in any Fabry-Perot resonator with a strongly wavelength-dependent mirror---can be exploited for realizing small modevolume and high quality factor microcavities and, if high mechanical quality suspended structured thin films are used, for optomechanics and optical sensing applications., Comment: 4 pages, 5 figures
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- 2018
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19. Effects of pressure on suspended micromechanical membrane arrays
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Naesby, Andreas, Naserbakht, Sepideh, and Dantan, Aurélien
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Condensed Matter - Mesoscale and Nanoscale Physics - Abstract
The effects of pressure on micromechanical air-filled cavities made by a pair of suspended, parallel silicon nitride membranes are investigated in the free molecular and quasi-molecular regimes. Variations of the fundamental drummode mechanical resonant frequencies and damping with air pressure are determined by means of optical interferometry. A kinetic damping linear friction force and a positive resonant frequency shift due to the compression of the fluid between the membranes are observed to be proportional with pressure in the range 0.01-10 mbars. For resonators with near-degenerate modes hybridization of the modes due to this squeeze film effect is also observed and well accounted for by a simple spring-coupled oscillator model., Comment: 4 pages, 3 figures
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- 2017
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20. Transient dynamics in cavity electromagnetically induced transparency with ion Coulomb crystals
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Albert, Magnus, Dantan, Aurélien, and Drewsen, Michael
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Quantum Physics ,Physics - Atomic Physics - Abstract
We experimentally investigate the transient dynamics of an optical cavity field interacting with large ion Coulomb crystals in a situation of electromagnetically induced transparency (EIT). EIT is achieved by injecting a probe field at the single photon level and a more intense control field with opposite circular polarization into the same mode of an optical cavity to couple Zeeman substates of a metastable level in 40Ca+ ions. The EIT interaction dynamics are investigated both in the frequency-domain - by measuring the probe field steady state reflectivity spectrum - and in the time-domain - by measuring the progressive buildup of transparency. The experimental results are observed to be in excellent agreement with theoretical predictions taking into account the inhomogeneity of the control field in the interaction volume, and confirm the high degree of control on light-matter interaction that can be achieved with ion Coulomb crystals in optical cavities., Comment: 15 pages, 10 figures
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- 2017
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21. Localization of ions within one-, two- and three-dimensional Coulomb crystals by a standing wave optical potential
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Lauprêtre, Thomas, Linnet, Rasmus B., Leroux, Ian D., Dantan, Aurélien, and Drewsen, Michael
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Quantum Physics ,Physics - Atomic Physics - Abstract
We demonstrate light-induced localization of Coulomb-interacting particles in multi-dimensional structures. Subwavelength localization of ions within small multi-dimensional Coulomb crystals by an intracavity optical standing wave field is evidenced by measuring the difference in scattering inside symmetrically red- and blue-detuned optical lattices and is observed even for ions undergoing substantial radial micromotion. These results are promising steps towards the structural control of ion Coulomb crystals by optical fields as well as for complex many-body simulations with ion crystals or for the investigation of heat transfer at the nanoscale, and have potential applications for ion-based cavity quantum electrodynamics, cavity optomechanics and ultracold ion chemistry.
- Published
- 2017
22. Light-matter interactions in multi-element resonators
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Genes, Claudiu and Dantan, Aurélien
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Quantum Physics - Abstract
We investigate structural resonances in multi-element optical resonators and provide a roadmap for the description of the interaction of single extended cavity modes with quantum emitters or mechanical resonators. Using a first principle approach based on the transfer matrix formalism we analyze, both numerically and analytically, the static and dynamical properties of three- and four-mirror cavities. We investigate in particular conditions under which the confinement of the field in specific subcavities allows for enhanced light-matter interactions in the context of cavity quantum electrodynamics and cavity optomechanics.
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- 2017
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23. Optomechanical characterization of silicon nitride membrane arrays
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Nair, Bhagya, Naesby, Andreas, and Dantan, Aurélien
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Physics - Optics ,Quantum Physics - Abstract
We report on the optical and mechanical characterization of arrays of parallel micromechanical membranes. Pairs of high-tensile stress, 100 nm-thick silicon nitride membranes are assembled parallel with each other with separations ranging from 8.5 to 200 $\mu$m. Their optical properties are accurately determined using a combination of broadband and monochromatic illuminations and the lowest vibrational mode frequencies and mechanical quality factors are determined interferometrically. The results and techniques demonstrated are promising for investigations of collective phenomena in optomechanical arrays., Comment: 5 pages, 5 figures
- Published
- 2017
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24. Cavity optomechanics with arrays of thick dielectric membranes
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Nair, Bhagya, Xuereb, André, and Dantan, Aurélien
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Quantum Physics ,Condensed Matter - Mesoscale and Nanoscale Physics ,Physics - Optics - Abstract
Optomechanical arrays made of structured flexible dielectrics are a promising system for exploring quantum and many-body optomechanical phenomena. We generalize investigations of the optomechanical properties of periodic arrays of one-dimensional scatterers in optical resonators to the case of vibrating membranes whose thickness is not necessarily small with respect to the optical wavelength of interest. The array optical transmission spectrum and its optomechanical coupling with a linear Fabry-Perot cavity field are investigated both analytically and numerically., Comment: 7 pages, 6 figures
- Published
- 2016
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25. Heat transport in harmonic oscillator systems with correlated baths: Application to optomechanical arrays
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Xuereb, André, Imparato, Alberto, and Dantan, Aurélien
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Quantum Physics ,Condensed Matter - Statistical Mechanics - Abstract
We investigate the transport of phonons between $N$ harmonic oscillators in contact with independent thermal baths and coupled to a common oscillator, and derive an expression for the steady state heat flow between the oscillators in the weak coupling limit. We apply these results to an optomechanical array consisting of a pair of mechanical resonators coupled to a single quantised electromagnetic field mode by radiation pressure as well as to thermal baths with different temperatures. In the weak coupling limit this system is shown to be equivalent to two mutually-coupled harmonic oscillators in contact with an effective common thermal bath in addition to their independent baths. The steady state occupation numbers and heat flows are derived and discussed in various regimes of interest., Comment: 18 pages, 3 figures
- Published
- 2014
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26. Squeeze Film Absolute Pressure Sensors with Sub-Millipascal Sensitivity
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Salimi, Mohsen, primary, Nielsen, Robin V., additional, Pedersen, Henrik, additional, and Dantan, Aurelien, additional
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- 2024
- Full Text
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27. Hybrid cavity mechanics with doped systems
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Dantan, Aurelien, Nair, Bhagya, Pupillo, Guido, and Genes, Claudiu
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Quantum Physics - Abstract
We investigate the dynamics of a mechanical resonator in which is embedded an ensemble of two-level systems interacting with an optical cavity field. We show that this hybrid approach to optomechanics allows for enhanced effective interactions between the mechanics and the cavity field, leading for instance to ground state cooling of the mechanics, even in regimes, like the unresolved sideband regime, in which standard radiation pressure cooling would be inefficient., Comment: 9 pages, 4 figures
- Published
- 2014
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28. Reconfigurable long-range phonon dynamics in optomechanical arrays
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Xuereb, André, Genes, Claudiu, Pupillo, Guido, Paternostro, Mauro, and Dantan, Aurélien
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Quantum Physics ,Condensed Matter - Mesoscale and Nanoscale Physics ,Physics - Optics - Abstract
We investigate periodic optomechanical arrays as reconfigurable platforms for engineering the coupling between multiple mechanical and electromagnetic modes and for exploring many-body phonon dynamics. Exploiting structural resonances in the coupling between light fields and collective motional modes of the array, we show that tunable effective long-range interactions between mechanical modes can be achieved. This paves the way towards the implementation of controlled phononic walks and heat transfer on densely-connected graphs as well as the coherent transfer of excitations between distant elements of optomechanical arrays., Comment: 11 pages, 7 figures
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- 2013
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29. Sub-Micron Positioning of Trapped Ions with Respect to the Absolute Center of a Standing Wave Cavity Field
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Linnet, Rasmus B., Leroux, Ian D., Dantan, Aurélien, and Drewsen, Michael
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Physics - Atomic Physics ,Quantum Physics - Abstract
We demonstrate that it is possible, with sub-micron precision, to locate the absolute center of a Fabry-P\'erot resonator oriented along the rf-field-free axis of a linear Paul trap through the application of two simultaneously resonating optical fields. In particular, we apply a probe field, which is near-resonant with an electronic transition of trapped ions, simultaneously with an off-resonant strong field acting as a periodic AC Stark-shifting potential. Through the resulting spatially modulated fluorescence signal we can find the cavity center of an 11.7 mm-long symmetric Fabry- P\'erot cavity with a precision of $\pm$135 nm, which is smaller than the periodicity of the individual standing wave fields. This can e.g. be used to position the minimum of the axial trap potential with respect to the center of the cavity at any location along the cavity mode., Comment: 6 pages, 4 figures; Text edited for clarity, results unchanged
- Published
- 2013
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30. Collectively-enhanced optomechanical coupling in periodic arrays of scatterers
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Xuereb, André, Genes, Claudiu, and Dantan, Aurélien
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Quantum Physics ,Physics - Atomic Physics ,Physics - Optics - Abstract
We investigate the optomechanical properties of a periodic array of identical scatterers placed inside an optical cavity and extend the results of [A. Xuereb, C. Genes, and A. Dantan, Phys. Rev. Lett. 109, 223601 (2012)]. We show that operating at the points where the array is transmissive results in linear optomechanical coupling strengths between the cavity field and collective motional modes of the array that may be several orders of magnitude larger than is possible with an equivalent reflective ensemble. We describe and interpret these effects in detail and investigate the nature of the scaling laws of the coupling strengths for the different transmissive points in various regimes., Comment: 14 pages, 14 figures, comments welcome. This is an expanded version of arXiv:1202.6210 with added interpretation and analysis
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- 2013
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31. Enhanced optomechanical readout using optical coalescence
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Genes, Claudiu, Xuereb, André, Pupillo, Guido, and Dantan, Aurélien
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Quantum Physics - Abstract
We present a scheme to strongly enhance the readout sensitivity of the squared displacement of a mobile scatterer placed in a Fabry-P\'erot cavity. We investigate the largely unexplored regime of cavity electrodynamics in which a highly reflective element positioned between the end mirrors of a symmetric Fabry-P\'erot resonator strongly modifies the cavity response function, such that two longitudinal modes with different spatial parity are brought close to frequency degeneracy and interfere in the cavity output field. In the case of a movable middle reflector we show that the interference in this generic "optical coalescence" phenomenon gives rise to an enhanced frequency shift of the peaks of the cavity transmission that can be exploited in optomechanics., Comment: 5 pages, 3 figures
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- 2013
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32. Pinning an Ion with an Intracavity Optical Lattice
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Linnet, Rasmus B., Leroux, Ian D., Marciante, Mathieu, Dantan, Aurélien, and Drewsen, Michael
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Physics - Atomic Physics ,Quantum Physics - Abstract
We report one-dimensional pinning of a single ion by an optical lattice. The lattice potential is produced by a standing-wave cavity along the rf-field-free axis of a linear Paul trap. The ion's localization is detected by measuring its fluorescence when excited by standing-wave fields with the same period, but different spatial phases. The experiments agree with an analytical model of the localization process, which we test against numerical simulations. For the best localization achieved, the ion's average coupling to the cavity field is enhanced from 50% to 81(3)% of its maximum possible value, and we infer that the ion is bound in a lattice well with over 97% probability., Comment: 5 pages, 4 figures; Text edited for clarity, results unchanged
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- 2012
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33. Strong coupling and long-range collective interactions in optomechanical arrays
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Xuereb, André, Genes, Claudiu, and Dantan, Aurélien
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Quantum Physics ,Condensed Matter - Mesoscale and Nanoscale Physics ,Physics - Atomic Physics ,Physics - Optics - Abstract
We investigate the collective optomechanics of an ensemble of scatterers inside a Fabry-Perot resonator and identify an optimized configuration where the ensemble is transmissive, in contrast with the usual reflective optomechanics approach. In this configuration, the optomechanical coupling of a specific collective mechanical mode can be several orders of magnitude larger than the single-element case, and long-range interactions can be generated between the different elements since light permeates throughout the array. This new regime should realistically allow for achieving strong single-photon optomechanical coupling with massive resonators, realizing hybrid quantum interfaces, and exploiting collective long-range interactions in arrays of atoms or mechanical oscillators., Comment: 11 pages, 12 figures
- Published
- 2012
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34. Spatial mode effects in a cavity EIT-based quantum memory with ion Coulomb crystals
- Author
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Zangenberg, Kasper R., Dantan, Aurélien, and Drewsen, Michael
- Subjects
Quantum Physics - Abstract
Quantum storage and retrieval of light in ion Coulomb crystals using cavity electromagnetically induced transparency is investigated theoretically. It is found that, when both the control and probe fields are coupled to the same cavity mode, their transverse mode profile affects the quantum memory efficiency in a non-trivial way. Under such conditions the control field parameters and crystal dimensions that maximize the memory efficiency are calculated., Comment: 15 pages, 7 figures
- Published
- 2012
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35. All-cavity electromagnetically induced transparency and optical switching: semiclassical theory
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Dantan, Aurelien, Albert, Magnus, and Drewsen, Michael
- Subjects
Quantum Physics - Abstract
The transmission of a probe field experiencing electromagnetically induced transparency and optical switching in an atomic medium enclosed in an optical cavity is investigated. Using a semiclassical input-output theory for the interaction between an ensemble of four-level atoms and three optical cavity fields coupled to the same spatial cavity mode, we derive the steady-state transmission spectra of the probe field and discuss the dynamics of the intracavity field buildup. The analytical and numerical results are in good agreement with recent experiments with ion Coulomb crystals [M. Albert et al., Nature Photon. 5, 633 (2011)]., Comment: 11 pages, 9 figures
- Published
- 2011
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36. Optical quantum swapping in a coherent atomic medium
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Dantan, Aurelien
- Subjects
Quantum Physics - Abstract
We propose to realize a passive optical quantum swapping device which allows for the exchange of the quantum fluctuations of two bright optical fields interacting with a coherent atomic medium in an optical cavity. The device is based on a quantum interference process between the fields within the cavity bandwidth arising from coherent population trapping in the atomic medium., Comment: 5 pages, 4 figures
- Published
- 2011
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37. Atom-mirror cooling and entanglement using cavity Electromagnetically Induced Transparency
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Genes, Claudiu, Ritsch, Helmut, Drewsen, Michael, and Dantan, Aurélien
- Subjects
Quantum Physics - Abstract
We investigate a hybrid optomechanical system comprised of a mechanical oscillator and an atomic 3-level ensemble within an optical cavity. We show that a suitably tailored cavity field response via Electromagnetically Induced Transparency (EIT) in the atomic medium allows for strong coupling of the mechanical mirror oscillations to the collective atomic ground-state spin. This facilitates ground-state cooling of the mirror motion, quantum state mapping and robust atom-mirror entanglement even for cavity widths larger than the mechanical oscillator frequency.
- Published
- 2011
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38. Cavity electromagnetically induced transparency and all-optical switching using ion Coulomb crystals
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Albert, Magnus, Dantan, Aurelien, and Drewsen, Michael
- Subjects
Quantum Physics - Abstract
The control of one light field by another, ultimately at the single photon level, is a challenging task which has numerous interesting applications within nonlinear optics and quantum information science. Due to the extremely weak direct interactions between optical photons in vacuum, this type of control can in practice only be achieved through highly nonlinear interactions within a medium. Electromagnetic induced transparency (EIT) constitutes one such means to obtain the extremely strong nonlinear coupling needed to facilitate interactions between two faint light fields. Here, we demonstrate for the first time EIT as well as all-optical EIT-based light switching using ion Coulomb crystals situated in an optical cavity. Unprecedented narrow cavity EIT feature widths down to a few kHz and a change from essentially full transmission to full absorption of the probe field within a window of only ~100 kHz are achieved. By applying a weak switching field, we furthermore demonstrate nearly perfect switching of the transmission of the probe field. These results represent important milestones for future realizations of quantum information processing devices, such as high-efficiency quantum memories, single-photon transistors and single-photon gates.
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- 2011
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39. A multimode model for projective photon-counting measurements
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Tualle-Brouri, Rosa, Ourjoumtsev, Alexei, Dantan, Aurelien, Grangier, Philippe, Wubs, Martijn, and Sorensen, Anders S.
- Subjects
Quantum Physics - Abstract
We present a general model to account for the multimode nature of the quantum electromagnetic field in projective photon-counting measurements. We focus on photon-subtraction experiments, where non-gaussian states are produced conditionally. These are useful states for continuous-variable quantum information processing. We present a general method called mode reduction that reduces the multimode model to an effective two-mode problem. We apply this method to a multimode model describing broadband parametric downconversion, thereby improving the analysis of existing experimental results. The main improvement is that spatial and frequency filters before the photon detector are taken into account explicitly. We find excellent agreement with previously published experimental results, using fewer free parameters than before, and discuss the implications of our analysis for the optimized production of states with negative Wigner functions., Comment: 14 pages, 9 figures
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- 2009
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40. Self-cooling of a movable mirror to the ground state using radiation pressure
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Dantan, Aurelien, Genes, Claudiu, Vitali, David, and Pinard, Michel
- Subjects
Quantum Physics - Abstract
We show that one can cool a micro-mechanical oscillator to its quantum ground state using radiation pressure in an appropriately detuned cavity (self-cooling). From a simple theory based on Heisenberg-Langevin equations we find that optimal self-cooling occurs in the good cavity regime, when the cavity bandwidth is smaller than the mechanical frequency, but still larger than the effective mechanical damping. In this case the intracavity field and the vibrational mechanical mode coherently exchange their fluctuations. We also present dynamical calculations which show how to access the mirror final temperature from the fluctuations of the field reflected by the cavity., Comment: 4 pages, 3 figures
- Published
- 2007
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41. Increasing entanglement between Gaussian states by coherent photon subtraction
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Ourjoumtsev, Alexei, Dantan, Aurelien, Tualle-Brouri, Rosa, and Grangier, Philippe
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Quantum Physics - Abstract
We experimentally demonstrate that the entanglement between Gaussian entangled states can be increased by non-Gaussian operations. Coherent subtraction of single photons from Gaussian quadrature-entangled light pulses, created by a non-degenerate parametric amplifier, produces delocalized states with negative Wigner functions and complex structures, more entangled than the initial states in terms of negativity. The experimental results are in very good agreement with the theoretical predictions.
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- 2006
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42. Spin-Squeezing and Light Entanglement in Coherent Population Trapping
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Dantan, Aurelien, Cviklinski, Jean, Giacobino, Elisabeth, and Pinard, Michel
- Subjects
Quantum Physics - Abstract
We show that high squeezing and entanglement can be generated at the output of a cavity containing atoms interacting with two fields in a Coherent Population Trapping situation, on account of a non-linear Faraday effect experienced by the fields close to a dark-state resonance in a cavity. Moreover, the cavity provides a feedback mechanism allowing to reduce the quantum fluctuations of the ground state spin, resulting in strong steady state spin-squeezing., Comment: 4 pages, 5 figures
- Published
- 2006
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43. Dynamics of a pulsed continuous variable quantum memory
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Dantan, Aurelien, Cviklinski, Jean, Pinard, Michel, and Grangier, Philippe
- Subjects
Quantum Physics - Abstract
We study the transfer dynamics of non-classical fluctuations of light to the ground-state collective spin components of an atomic ensemble during a pulsed quantum memory sequence, and evaluate the relevant physical quantities to be measured in order to characterize such a quantum memory. We show in particular that the fluctuations stored into the atoms are emitted in temporal modes which are always different than those of the readout pulse, but which can nevertheless be retrieved efficiently using a suitable temporal mode-matching technique. We give a simple toy model - a cavity with variable transmission - which accounts for the behavior of the atomic quantum memory., Comment: 6 pages, 5 figures
- Published
- 2005
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44. Squeezing and entangling nuclear spins in helium 3
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Reinaudi, Gael, Sinatra, Alice, Dantan, Aurelien, and Pinard, Michel
- Subjects
Quantum Physics - Abstract
We present a realistic model for transferring the squeezing or the entanglement of optical field modes to the collective ground state nuclear spin of $^3$He using metastability exchange collisions. We discuss in detail the requirements for obtaining good quantum state transfer efficiency and study the possibility to readout the nuclear spin state optically.
- Published
- 2005
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45. Entangling movable mirrors in a double cavity system
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Pinard, Michel, Dantan, Aurelien, Vitali, David, Arcizet, Olivier, Briant, Tristan, and Heidmann, Antoine
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Quantum Physics - Abstract
We propose a double-cavity set-up capable of generating a stationary entangled state of two movable mirrors at cryogenic temperatures. The scheme is based on the optimal transfer of squeezing of input optical fields to mechanical vibrational modes of the mirrors, realized by the radiation pressure of the intracavity light. We show that the presence of macroscopic entanglement can be demonstrated by an appropriate read out of the output light of the two cavities., Comment: to appear in Europhysics Letters
- Published
- 2005
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46. Long-lived quantum memory with nuclear atomic spins
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Dantan, Aurelien, Reinaudi, Gael, Sinatra, Alice, Laloë, Franck, Giacobino, Elisabeth, and Pinard, Michel
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Quantum Physics - Abstract
We propose to store non-classical states of light into the macroscopic collective nuclear spin ($10^{18}$ atoms) of a $^3$He vapor, using metastability exchange collisions. These collisions, commonly used to transfer orientation from the metastable state $2^{3}S\_1$ to the ground state state of $^3$He, can also transfer quantum correlations. This gives a possible experimental scheme to map a squeezed vacuum field state onto a nuclear spin state with very long storage times (hours)., Comment: 4 pages
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- 2005
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47. Atomic quantum memory: cavity vs single pass schemes
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Dantan, Aurelien, Bramati, Alberto, and Pinard, Michel
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Quantum Physics - Abstract
This paper presents a quantum mechanical treatment for both atomic and field fluctuations of an atomic ensemble interacting with propagating fields, either in Electromagnetically Induced Transparency or in a Raman situation. The atomic spin noise spectra and the outgoing field spectra are calculated in both situations. For suitable parameters both EIT and Raman schemes efficiently preserve the quantum state of the incident probe field in the transfer process with the atoms, although a single pass scheme is shown to be intrinsically less efficient than a cavity scheme.
- Published
- 2004
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48. Teleportation of an atomic ensemble quantum state
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Dantan, Aurelien, Treps, Nicolas, Bramati, Alberto, and Pinard, Michel
- Subjects
Quantum Physics - Abstract
We propose a protocol to achieve high fidelity quantum state teleportation of a macroscopic atomic ensemble using a pair of quantum-correlated atomic ensembles. We show how to prepare this pair of ensembles using quasiperfect quantum state transfer processes between light and atoms. Our protocol relies on optical joint measurements of the atomic ensemble states and magnetic feedback reconstruction.
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- 2004
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49. Manipulation and storage of optical field and atomic ensemble quantum states
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Dantan, Aurelien, Bramati, Alberto, Pinard, Michel, and Giacobino, Elisabeth
- Subjects
Quantum Physics - Abstract
We study how to efficiently manipulate and store quantum information between optical fields and atomic ensembles. We show how various non-dissipative transfer schemes can be used to transfer and store quantum states such as squeezed vacuum states or entangled states into the long-lived ground state spins of atomic ensembles., Comment: Contribution to Laser Physics special issue in honor of pr Herbert Walther 70's birthday
- Published
- 2004
50. Entanglement storage in atomic ensembles
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Dantan, Aurelien, Bramati, Alberto, and Pinard, Michel
- Subjects
Quantum Physics - Abstract
We propose to entangle macroscopic atomic ensembles in cavity using EPR-correlated beams. We show how the field entanglement can be almost perfectly mapped onto the long-lived atomic spins associated with the ground states of the ensembles, and how it can be retrieved in the fields exiting the cavities after a variable storage time. Such a continuous variable quantum memory is of interest for manipulating entanglement in quantum networks.
- Published
- 2004
- Full Text
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