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(180) Production(s) de ANTEZZA M.
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ThermalandElectrostaticManipulationoftheCasimirForceinGrapheneMultilayers
Auteur(s): Guizal B., Abbas C., Antezza M.
Conférence invité: Global summit on Laser Optics & Photonics (Valencia, ES, 2017-06-19)
Ref HAL: hal-01548335_v1
Exporter : BibTex | endNote
Résumé: We show that graphene-dielectric multilayers give rise to an unusual tunability of the Casimir-Lifshitz forces and allow to easily realize completely different regimes within the same structure. Concerning thermal effects, graphene-dielectric multilayers take advantage of the anomalous features predicted for isolated suspended graphene sheets, even though they are considerably affected by the presence of the dielectric substrate. They can also achieve the anomalous nonmonotonic thermal metallic behavior by increasing the graphene sheets density and their Fermi level. In addition to a strong thermal modulation occurring at short separations, in a region where the force is orders of magnitude larger than the one occurring at large distances, the force can be also adjusted by varying the number of graphene layers as well as their Fermi levels, allowing for relevant force amplifications which can be tuned, very rapidly and in situ, by simply applying an electric potential. Our predictions can be relevant for both Casimir experiments and micro- or nanoelectromechanical systems and in new devices for technological applications.
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Radiative Heat Transfer between Metallic Gratings Using Adaptive Spatial Resolution
Auteur(s): Guizal B., Messina R., Noto A., Antezza M.
Conférence invité: PIERS : Progress In Electromagnetics Research Symposium (Saint Petersbourg, RU, 2017-05-22)
Ref HAL: hal-01538779_v1
Exporter : BibTex | endNote
Résumé: We calculate the radiative heat transfer between two identical metallic one-dimensional lamellar gratings. To this aim we present and exploit a modification to the widely-used Fourier modal method, known as adaptive spatial resolution, based on a stretch of the coordinate associated to the periodicity of the grating. We first show that this technique dramatically improves the rate of convergence when calculating the heat flux. We then present a study of heat flux as a function of the grating height, highlighting a remarkable amplification of the exchanged energy, ascribed to the appearance of spoof-plasmon modes, whose behavior is also spectrally investigated. Differ- ently from previous works, our method allows us to explore a range of grating heights extending over several orders of magnitude. By comparing our results to recent studies we find a consis- tent quantitative disagreement with some previously obtained results going up to 50%. In some cases, this disagreement is explained in terms of an incorrect connection between the reflection operators of the two gratings.
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Robust entanglement with three-dimenstional nonreciprocal photonic topological insulators
Auteur(s): Hassani Gangaraj S. Ali, Hanson George W., Antezza M.
(Article) Publié:
-Physical Review A Atomic, Molecular, And Optical Physics [1990-2015], vol. 95 p.063807 (2017)
Texte intégral en Openaccess :
Ref HAL: hal-01533723_v1
DOI: 10.1103/PhysRevA.95.063807
WoS: 000402794000009
Exporter : BibTex | endNote
14 Citations
Résumé: We investigate spontaneous and pumped entanglement of two-level systems in the vicinity of a photonic topological insulator interface, which supports a nonreciprocal (unidirectional), scattering-immune, and topologically protected surface-plasmon polariton in the band gap of the bulk material. To this end, we derive a master equation for qubit interactions in a general three-dimensional, nonreciprocal, inhomogeneous, and lossy environment. The environment is represented exactly, via the photonic Green's function. The resulting entanglement is shown to be extremely robust to defects occurring in the material system, such that strong entanglement is maintained even if the interface exhibits electrically large and geometrically sharp discontinuities. Alternatively, depending on the initial excitation state, using a nonreciprocal environment allows two qubits to remain unentangled even for very close spacing. The topological nature of the material is manifest in the insensitivity of the entanglement to variations in the material parameters that preserve the gap Chern number. Our formulation and results should be useful for both fundamental investigations of quantum dynamics in nonreciprocal environments and technological applications related to entanglement in two-level systems.
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Radiative heat transfer and nonequilibrium Casimir-Lifshitz force in many-body systems with planar geometry
Auteur(s): Latella Ivan, Ben-Abdallah Philippe, Biehs Svend-Age, Antezza M., Messina R.
(Article) Publié:
Physical Review B, vol. 95 p.205404 (2017)
Texte intégral en Openaccess :
Ref HAL: hal-01517943_v1
DOI: 10.1103/PhysRevB.95.205404
WoS: 000400661700005
Exporter : BibTex | endNote
27 Citations
Résumé: A general theory of photon-mediated energy and momentum transfer in N-body planar systems out of thermal equilibrium is introduced. It is based on the combination of the scattering theory and the fluctuational electrodynamics approach in many-body systems. By making a Landauer-like formulation of the heat transfer problem, explicit formulas for the energy transmission coefficients between two distinct slabs as well as the self-coupling coefficients are derived and expressed in terms of the reflection and transmission coefficients of the single bodies. We also show how to calculate local equilibrium temperatures in such systems. An analogous formulation is introduced to quantify momentum transfer coefficients describing Casimir-Lifshitz forces out of thermal equilibrium. Forces at thermal equilibrium are readily obtained as a particular case. As an illustration of this general theoretical framework, we show on three-body systems how the presence of a fourth slab can impact equilibrium temperatures in heat-transfer problems and equilibrium positions resulting from the forces acting on the system.
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Strong Thermal and Electrostatic Manipulation of the Casimir Force in Graphene Multilayers
Auteur(s): Abbas C., Guizal B., Antezza M.
(Article) Publié:
Physical Review Letters, vol. 118 p.126101 (2017)
Texte intégral en Openaccess :
Ref HAL: hal-01494732_v1
DOI: 10.1103/PhysRevLett.118.126101
WoS: 000397804300011
Exporter : BibTex | endNote
10 Citations
Résumé: We show that graphene-dielectric multilayers give rise to an unusual tunability of the Casimir-Lifshitz forces and allow to easily realize completely different regimes within the same structure. Concerning thermal effects, graphene-dielectric multilayers take advantage of the anomalous features predicted forisolated suspended graphene sheets, even though they are considerably affected by the presence of the dielectric substrate. They can also achieve the anomalous nonmonotonic thermal metallic behavior by increasing the graphene sheets density and their Fermi level. In addition to a strong thermal modulation occurring at short separations, in a region where the force is orders of magnitude larger than the one occurring at large distances, the force can be also adjusted by varying the number of graphene layers as well as their Fermi levels, allowing for relevant force amplifications which can be tuned, very rapidly and in situ, by simply applying an electric potential. Our predictions can be relevant for both Casimir experiments and micro- or nanoelectromechanical systems and in new devices for technological applications.
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Radiative heat transfer between metallic gratings using Fourier modal method with adaptive spatial resolution
Auteur(s): Messina R., Noto A., Guizal B., Antezza M.
(Article) Publié:
Physical Review B, vol. 95 p.125404 (2017)
Texte intégral en Openaccess :
Ref HAL: hal-01482013_v1
DOI: 10.1103/PhysRevB.95.125404
WoS: 000396010400005
Exporter : BibTex | endNote
25 Citations
Résumé: We calculate the radiative heat transfer between two identical metallic one-dimensional lamellar gratings. To this aim we present and exploit a modification to the widely used Fourier modal method, known as adaptive spatial resolution, based on a stretch of the coordinate associated with the periodicity of the grating. We first show that this technique dramatically improves the rate of convergence when calculating the heat flux, allowing us to explore smaller separations. We then present a study of heat flux as a function of the grating height, highlighting a remarkable amplification of the exchanged energy, ascribed to the appearance of spoof-plasmon modes, whose behavior is also spectrally investigated. Differently from previous works, our method allows us to explore a range of grating heights extending over several orders of magnitude. By comparing our results to recent studies we find a consistent quantitative disagreement with some previously obtained results going up to 50%. In some cases, this disagreement is explained in terms of an incorrect connection between the reflection operators of the two gratings.
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Many body heat radiation and heat transfer in the presence of a non-absorbing background medium
Auteur(s): Boris Muller, Roberta Incardone, Antezza M., Thorsten Emig, Matthias Kruger
(Article) Publié:
Physical Review B, vol. 95 p.085413 (2017)
Texte intégral en Openaccess :
Ref HAL: hal-01464078_v1
DOI: 10.1103/PhysRevB.95.085413
WoS: 000393590900004
Exporter : BibTex | endNote
22 Citations
Résumé: Heat radiation and near-field radiative heat transfer can be strongly manipulated by adjusting geometrical shapes, optical properties, or the relative positions of the objects involved. Typically, these objects are considered as embedded in vacuum. By applying the methods of fluctuational electrodynamics, we derive general closed-form expressions for heat radiation and heat transfer in a system of N arbitrary objects embedded in a passive nonabsorbing background medium. Taking into account the principle of reciprocity, we explicitly prove the symmetry and positivity of transfer in any such system. Regarding applications, we find that the heat radiation of a sphere as well as the heat transfer between two parallel plates is strongly enhanced by the presence of a background medium. Regarding near- and far-field transfer through a gas like air, we show that a microscopic model (based on gas particles) and a macroscopic model (using a dielectric contrast) yield identical results. We also compare the radiative transfer through a medium like air and the energy transfer found from kinetic gas theory.
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