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Physique de l'exciton, du photon et du spin
(59) Production(s) de l'année 2024
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Favorable and unfavorable many-body interactions for near-field radiative heat transfer in nanoparticle networks
Auteur(s): Luo M., Zhao Junming, Liu Linhua, Antezza M.
(Article) Publié:
Journal Of Quantitative Spectroscopy And Radiative Transfer, vol. 327 p.109129 (2024)
Texte intégral en Openaccess :
Ref HAL: hal-04881058_v1
Ref Arxiv: 2310.11273
DOI: 10.1016/j.jqsrt.2024.109129
Ref. & Cit.: NASA ADS
Exporter : BibTex | endNote
Résumé: Near-field radiative heat transfer (NFRHT) in point-dipole nanoparticle networks is complicated due to the multiple scattering of thermally excited electromagnetic wave (namely, many-body interaction, MBI). The MBI regime is analyzed using the many-body radiative heat transfer theory at the particle scale for networks of a few nanoparticles. Effect of MBI on radiative heat diffusion in networks of a large number of nanoparticles is analyzed using the normal-diffusion radiative heat transfer theory at the continuum scale. An influencing factor is defined to numerically figure out the border of the different many-body interaction regimes. The whole space near the two nanoparticles can be divided into four zones, non-MBI zone, enhancement zone, inhibition zone and forbidden zone, respectively. Enhancement zone is relatively smaller than the inhibition zone, so many particles can lie in the inhibiting zone that the inhibition effect of many-body interaction on NFRHT in nanoparticle networks is common in literature. Analysis on the radiative thermal energy confirms that multiple scattering caused by the inserted scatterer accounts for the enhancement and inhibition of NFRHT. By arranging the nanoparticle network in aspect of structures and optical properties, the MBI can be used to modulate radiative heat diffusion characterized by the radiative effective thermal conductivity () over a wide range, from inhibition (over 55% reduction) to amplification (30 times of magnitude). To achieve a notable MBI, it is necessary to introduce particles that have resonances well-matched with those of the particles of interest, irrespective of their match with the Planckian window. This work may help for the understanding of the thermal radiation in nanoparticle networks.
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Spontaneous breaking of time-reversal symmetry and time-crystal states in chiral atomic systems
Auteur(s): Antezza M.
Conférence invité: FQMT 2024 - Frontiers of Quantum and Mesoscopic Thermodynamics (Prague (Czech Republic), CZ, 2024-07-22)
Ref HAL: hal-04844720_v1
Exporter : BibTex | endNote
Résumé: We present a theoretical study of the interaction between an atom characterized by a degenerate ground state and a reciprocal environment, such as a semiconductor nanoparticle, without the presence of external bias. Our analysis reveals that the combined influence of the electron's intrinsic spin magnetic moment on the environment and the chiral atomic dipolar transitions may lead to either the spontaneous breaking of time-reversal symmetry or the emergence of time-crystal-like states with remarkably long relaxation times. The different behavior is ruled by the handedness of the precession motion of the atom's spin vector, which is induced by virtual chiral-dipolar transitions. Specifically, when the relative orientation of the precession angular velocity and the electron spin vector is as in a spinning top, the system manifests time-crystal-like states. Conversely, with the opposite relative orientation, the system experiences spontaneous symmetry breaking of time reversal symmetry. Our findings introduce a mechanism for the spontaneous breaking of time-reversal symmetry in atomic systems, and unveil an exciting opportunity to engineer a nonreciprocal response at the nanoscale, exclusively driven by the quantum vacuum fluctuations.
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On the different models of Graphene conductivity and its effects on Casimir forces and on radiative heat transfer in nanostructured systems
Auteur(s): Antezza M.
Conférence invité: META 2024 - The 14th International Conference on Metamaterials, Photonic Crystals and Plasmonics (Toyama, Japon, JP, 2024-07-17)
Ref HAL: hal-04845546_v1
Exporter : BibTex | endNote
Résumé: We discuss different available models of graphene conductivity, and their effects on two main fluctuational electrodynamics phenomena in nanostructured systems.
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Spontaneous breaking of time-reversal symmetry and time-crystal states in chiral atomic systems
Auteur(s): Antezza M.
(Séminaires)
Department of Physics, National University of Singapore (NUS) (Singapour, SG), 2024-07-11
Résumé: We present a theoretical study of the interaction between an atom characterized by a degenerate ground state and a reciprocal environment, such as a semiconductor nanoparticle, without the presence of external bias. Our analysis reveals that the combined influence of the electron's intrinsic spin magnetic moment on the environment and the chiral atomic dipolar transitions may lead to either the spontaneous breaking of time-reversal symmetry or the emergence of time-crystal-like states with remarkably long relaxation times. The different behavior is ruled by the handedness of the precession motion of the atom's spin vector, which is induced by virtual chiral-dipolar transitions. Specifically, when the relative orientation of the precession angular velocity and the electron spin vector is as in a spinning top, the system manifests time-crystal-like states. Conversely, with the opposite relative orientation, the system experiences spontaneous symmetry breaking of time reversal symmetry. Our findings introduce a mechanism for the spontaneous breaking of time-reversal symmetry in atomic systems, and unveil an exciting opportunity to engineer a nonreciprocal response at the nanoscale, exclusively driven by the quantum vacuum fluctuations.
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Fluctuational electrodynamics effects in graphene-based nanosystems
Auteur(s): Antezza M.
Conférence invité: AES 2024, The International Conference on Antennas and Electromagnetic Systems (Rome (Italie), IT, 2024-06-25)
Ref HAL: hal-04845553_v1
Exporter : BibTex | endNote
Résumé: We discuss graphene effects on two main fluctuational electrodynamics: Casimir effect and radiative heat transfer.
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Near-field radiative heat transfer between a nanoparticle and a graphene grating
Auteur(s): Luo M., Jeyar Y., Guizal B., Antezza M.
(Document sans référence bibliographique) 2024-06-09Texte intégral en Openaccess :
Ref HAL: hal-04617593_v1
Ref Arxiv: 2406.05921
DOI: 10.48550/arXiv.2406.05921
Ref. & Cit.: NASA ADS
Exporter : BibTex | endNote
Résumé: We investigate the near-field radiative heat transfer between a normally and/or laterally shifted nanoparticle and a planar fused silica slab coated with a strip graphene grating. For this study we develop and use a scattering matrix approach derived from Fourier modal method augmented with local basis functions. We find that adding a graphene sheet coating on the slab can already enhance the heat flux by about 85%. We show that by patterning the graphene sheet coating into a grating, the heat flux is further increased, and this happens thanks to the a topological transition of the plasmonic modes from circular to hyperbolic one, which allows for more energy transfer. The lateral shift affects the accessible range of high-$k$ modes and thus affects the heat flux, too. By moving the nanoparticle laterally above the graphene grating, we can obtain an optimal heat flux with strong chemical potential dependance above the strips. For a fixed graphene grating period ($D=1μ$m) and not too large normal shift (separation $d<800$nm), two different types of lateral shift effects (e.g., enhancement and inhibition) on heat transfer have been observed. As the separation $d$ is further increased, the lateral shift effect becomes less important. We show that the lateral shift effect is sensitive to the geometric factor $d/D$. Two distinct asymptotic regimes are proposed: (1) the inhibition regime ($d/D<0.85$), where the lateral shift reduces the heat transfer, and (2) the neutral regime ($d/D \geq 0.85$) where the effect of the lateral shift is negligible. In general, we can say that the geometric factor $d/D \approx 0.85$ is a critical point for the lateral shift effect. Our predictions can have relevant implications to the radiative heat transfer and energy management at the nano/micro scale.
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Gain-loss-engineering: a new platform for extreme anisotropic thermal photon tunneling
Auteur(s): Zhou Cheng-Long, Peng Yu-Chen, Zhang Yong, Yi Hong-Liang, Antezza M., Galdi Vincenzo
(Document sans référence bibliographique) 2024-05-25Texte intégral en Openaccess :
Ref HAL: hal-04617573_v1
Ref Arxiv: 2405.16109
DOI: 10.48550/arXiv.2405.16109
Ref. & Cit.: NASA ADS
Exporter : BibTex | endNote
Résumé: We explore a novel approach to achieving anisotropic thermal photon tunneling, inspired by the concept of parity-time symmetry in quantum physics. Our method leverages the modulation of constitutive optical parameters, oscillating between loss and gain regimes. This modulation reveals a variety of distinct effects in thermal photon behavior and dispersion. Specifically, we identify complex tunneling modes through gain-loss engineering, which include thermal photonic defect states and Fermi-arc-like phenomena, which surpass those achievable through traditional polariton engineering. Our research also elucidates the laws governing the evolution of radiative energy in the presence of gain and loss interactions, and highlights the unexpected inefficacy of gain in enhancing thermal photon energy transport compared to systems characterized solely by loss. This study not only broadens our understanding of thermal photon tunneling but also establishes a versatile platform for manipulating photon energy transport, with potential applications in thermal management, heat science, and the development of advanced energy devices.
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