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(180) Production(s) de ANTEZZA M.
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Robust entanglement with three-dimensional nonreciprocal photonic topological insulators
Auteur(s): Antezza M.
Conférence invité: Optics 2017 (Barcelone, ES, 2017-06-20)
Ref HAL: hal-01909499_v1
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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 bandgap of the bulk material [1]. 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 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 non-reciprocal 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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Robust Entanglement and Giant Interatomic Energy-Transport with Photonic Topological Insulators
Auteur(s): Antezza M.
(Séminaires)
Institut de Phyique - INPHYNI (Nice, FR), 2017-09-05 |
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Casimir-Lifshitz force for nonreciprocal media and applications to photonic topological insulators
Auteur(s): Fuchs Sebastian, Lindel Frider, Krems Roman, Hanson George W., Antezza M., Buhmann Stefan Yoshi
(Article) Publié:
-Physical Review A Atomic, Molecular, And Optical Physics [1990-2015], vol. 96 p.062505 (2017)
Texte intégral en Openaccess :
Ref HAL: hal-01664518_v1
DOI: 10.1103/PhysRevA.96.062505
WoS: 000417919200004
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9 Citations
Résumé: Based on the theory of macroscopic quantum electrodynamics, we generalize the expression of the Casimir force for nonreciprocal media. The essential ingredient of this result is the Green’s tensor between two nonreciprocal semi-infinite slabs, including a reflexion matrix with four coefficients that mixes optical polarizations. This Green’s tensor does not obey Lorentz’s reciprocity and thus violates time-reversal symmetry. The general result for the Casimir force is analyzed in the retarded and nonretarded limits, concentrating on the influences arising from reflections with or without change of polarization. In a second step, we apply our general result to a photonic topological insulator whose nonreciprocity stems from an anisotropic permittivity tensor, namely InSb. We show that there is a regime for the distance between the slabs where the magnitude of the Casimir force is tunable by an external magnetic field. Furthermore, the strength of this tuning depends on the orientation of the magnetic field with respect to the slab surfaces.
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Giant Interatomic Energy-Transport Amplification with Nonreciprocal Photonic Topological Insulators
Auteur(s): Doyeux P., Hassani Gangaraj S. Ali, Hanson George W., Antezza M.
(Article) Publié:
Physical Review Letters, vol. 119 p.173901 (2017)
Texte intégral en Openaccess :
Ref HAL: hal-01624891_v1
DOI: 10.1103/PhysRevLett.119.173901
WoS: 000413770200001
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9 Citations
Résumé: We show that the energy-transport efficiency in a chain of two-level emitters can be drastically enhanced by the presence of a photonic topological insulator (PTI). This is obtained by exploiting the peculiar properties of its nonreciprocal surface plasmon polariton (SPP), which is unidirectional, and immune to backscattering, and propagates in the bulk band gap. This amplification of transport efficiency can be as much as 2 orders of magnitude with respect to reciprocal SPPs. Moreover, we demonstrate that despite the presence of considerable imperfections at the interface of the PTI, the efficiency of the SPP-assisted energy transport is almost unaffected by discontinuities. We also show that the SPP properties allow energy transport over considerably much larger distances than in the reciprocal case, and we point out aparticularly simple way to tune the transport. Finally, we analyze the specific case of a two-emitter chain and unveil the origin of the efficiency amplification. The efficiency amplification and the practical advantages highlighted in this work might be particularly useful in the development of new devices intended to manage energy at the atomic scale.
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Radiative heat-transfer between metallic gratings using adaptive spatial resolution
Auteur(s): Messina R., Noto A., Guizal B., Antezza M.
Conférence invité: META'17 - Incheon – Korea (Incheon - Seoul, KR, 2017-07-25)
Ref HAL: hal-01570566_v1
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Résumé: We calculate the radiative heat transfer between two metallic gratings by exploiting the Adaptive Spatial Resolution metod. This technique dramatically improves the rate of convergence allowing to explore smaller separations. The heat flux shows a remarkable amplification of the exchanged energy, due to spoof-plasmon modes. We find a consistent disagreement with some previously obtained results going up to 50% (this disagreement is explained in terms of an incorrect connection between the reflection operators of the two gratings).
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Graphene-based amplification and tuning of near-field radiative heat transfer between dissimilar polar materials
Auteur(s): Messina R., Ben-Abdallah Philippe, Guizal B., Antezza M.
(Article) Publié:
Physical Review B, vol. 96 p.045402 (2017)
Texte intégral en Openaccess :
Ref HAL: hal-01557223_v1
DOI: 10.1103/PhysRevB.96.045402
WoS: 000405026300018
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19 Citations
Résumé: The radiative heat transfer between two dielectrics can be strongly enhanced in the near field in the presence of surface phonon-polariton resonances. Nevertheless, the spectral mismatch between the surface modes supported by two dissimilar materials is responsible for a dramatic reduction of the radiative heat flux they exchange. In the present paper we study how the presence of a graphene sheet, deposited on the material supporting the surfacewave of lowest frequency, allows us to widely tune the radiative heat transfer, producing an amplification factor going up to one order of magnitude. By analyzing the Landauer energy transmission coefficients we demonstratethat this amplification results from the interplay between the delocalized plasmon supported by graphene and the surface polaritons of the two dielectrics. We finally show that the effect we highlight is robust with respect to the frequency mismatch, paving the way to an active tuning and amplification of near-field radiative heat transfer in different configurations.
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Near-field heat transfer between graphene/hBN multilayers
Auteur(s): Zhao Bo, Guizal B., Zhang Z., Fan Shanhui, Antezza M.
(Article) Publié:
Physical Review B, vol. 95 p.245437 (2017)
Texte intégral en Openaccess :
Ref HAL: hal-01552158_v1
DOI: 10.1103/PhysRevB.95.245437
WoS: 000404470200013
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41 Citations
Résumé: We study the radiative heat transfer between multilayer structures made by a periodic repetition of a graphene sheet and a hexagonal boron nitride (hBN) slab. Surface plasmons in a monolayer graphene can couple withhyperbolic phonon polaritons in a single hBN film to form hybrid polaritons that can assist photon tunneling. For periodic multilayer graphene/hBN structures, the stacked metallic/dielectric array can give rise to a further effective hyperbolic behavior, in addition to the intrinsic natural hyperbolic behavior of hBN. The effective hyperbolicity can enable more hyperbolic polaritons that enhance the photon tunneling and hence the near-fieldheat transfer. However, the hybrid polaritons on the surface, i.e., surface plasmon-phonon polaritons, dominate the near-field heat transfer between multilayer structures when the topmost layer is graphene. The effectivehyperbolic regions can be well predicted by the effective medium theory (EMT), thought EMT fails to capture the hybrid surface polaritons and results in a heat transfer rate much lower compared to the exact calculation. The chemical potential of the graphene sheets can be tuned through electrical gating and results in an additional modulation of the heat transfer. We found that the near-field heat transfer between multilayer structures does not increase monotonously with the number of layers in the stack, which provides a way to control the heat transfer rate by the number of graphene layers in the multilayer structure. The results may benefit the applications of near-field energy harvesting and radiative cooling based on hybrid polaritons in two-dimensional materials.
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