Your search keyword '"Guérout, R."' showing total 20 results

1. Scattering theory of the screened Casimir interaction in electrolytes

Author

Neto, P. A. Maia, Rosa, F. S. S., Pires, L. B., Marim, A. B., Canaguier-Durand, A., Guérout, R., Lambrecht, A., and Reynaud, S.

Subjects

Condensed Matter - Mesoscale and Nanoscale Physics, Quantum Physics

Abstract

We apply the scattering approach to the Casimir interaction between two dielectric half-spaces separated by an electrolyte solution. We take the nonlocal electromagnetic response of the intervening medium into account, which results from the presence of movable ions in solution. In addition to the usual transverse modes, we consider longitudinal channels and their coupling by reflection at the surface of the local dielectric. The Casimir interaction energy is calculated from the matrix describing a round-trip of coupled transverse and longitudinal waves between the interacting surfaces. The nonzero-frequency contributions are approximately unaffected by the presence of ions. We find, at zero frequency, a contribution from longitudinal channels, which is screened over a distance of the order of the Debye length, alongside an unscreened term arising from transverse-magnetic modes. The latter defines the long-distance asymptotic limit for the interaction., Comment: 9 pages, 3 figures

Published

2019

2. Quantum interference test of the equivalence principle on antihydrogen

Author

Crépin, P. -P., Christen, C., Guérout, R., Nesvizhevsky, V. V., Voronin, A. Yu., and Reynaud, S.

Subjects

Quantum Physics

Abstract

We propose to use quantum interferences to improve the accuracy of the measurement of the free fall acceleration g of antihydrogen in the GBAR experiment. This method uses most antiatoms prepared in the experiment and it is simple in its principle as interferences between gravitational quantum states are readout without transitions between them. We use a maximum likelihood method for estimating the value of g and assess the accuracy of this estimation by a Monte-Carlo simulation. We find that the accuracy is improved by approximately three orders of magnitude with respect to the classical timing technique planned for the current design of the experiment., Comment: 8 figures

Published

2019

3. Spontaneous emission of a sodium Rydberg atom close to an optical nanofibre

Author

Stourm, E, Zhang, Y, Lepers, M, Guérout, R, Robert, J, Chormaic, S Nic, Mølmer, K., and Brion, E.

Subjects

Quantum Physics

Abstract

We report on numerical calculations of the spontaneous emission rate of a Rydberg-excited sodium atom in the vicinity of an optical nanofibre. In particular, we study how this rate varies with the distance of the atom to the fibre, the fibre's radius, the symmetry s or p of the Rydberg state as well as its principal quantum number. We find that a fraction of the spontaneously emitted light can be captured and guided along the fibre. This suggests that such a setup could be used for networking atomic ensembles, manipulated in a collective way due to the Rydberg blockade phenomenon.

Published

2018

4. Accounting for dissipation in the scattering approach to the Casimir energy

Author

Guérout, R., Ingold, G. -L., Lambrecht, A., and Reynaud, S.

Subjects

Quantum Physics

Abstract

We take dissipation into account in the derivation of the Casimir energy formula between two objects placed in a surrounding medium. The dissipation channels are considered explicitly in order to take advantage of the unitarity of the full scattering processes. We demonstrate that the Casimir energy is given by a scattering formula expressed in terms of the scattering amplitudes coupling internal channels and taking dissipation into account in an implicit way. We prove that this formula is also valid when the surrounding medium is dissipative., Comment: 11 pages, 4 figures

Published

2018

5. Quantum reflection of antihydrogen from a liquid helium film

Author

Crépin, P. -P., Kupriyanova, E. A., Guérout, R., Lambrecht, A., Nesvizhevsky, V. V., Reynaud, S., Vasiliev, S., and Voronin, A. Yu.

Subjects

Physics - Atomic Physics

Abstract

We study the quantum reflection of ultracold antihydrogen atoms bouncing on the surface of a liquid helium film. The Casimir-Polder potential and quantum reflection are calculated for different thicknesses of the film supported by different substrates. Antihydrogen can be protected from anni- hilation for as long as 1.3s on a bulk of liquid 4He, and 1.7s for liquid 3He. These large lifetimes open interesting perspectives for spectroscopic measurements of the free fall acceleration of antihydrogen. Variation of the scattering length with the thickness of a film of helium shows interferences which we interpret through a Liouville transformation of the quantum reflection problem.

Published

2017

6. Casimir-Polder shifts on quantum levitation states

Author

Crépin, P. -P., Dufour, G., Guérout, R., Lambrecht, A., and Reynaud, S.

Subjects

Quantum Physics

Abstract

An ultracold atom above a horizontal mirror experiences quantum reflection from the attractive Casimir-Polder interaction, which holds it against gravity and leads to quantum levitation states. We analyze this system by using a Liouville transformation of the Schr\"odinger equation and a Langer coordinate adapted to problems with a classical turning point. Reflection on the Casimir-Polder attractive well is replaced by reflection on a repulsive wall and the problem is then viewed as an ultracold atom trapped inside a cavity with gravity and Casimir-Polder potentials acting respectively as top and bottom mirrors. We calculate numerically Casimir-Polder shifts of the energies of the cavity resonances and propose a new approximate treatment which is precise enough to discuss spectroscopy experiments aiming at tests of the weak equivalence principle on antihydrogen. We also discuss the lifetimes by calculating complex energies associated with cavity resonances., Comment: Accepted in PRA

Published

2016

7. Surface-modified Wannier-Stark states in a 1D optical lattice

Author

Maury, A., Donaire, M., Gorza, M. -P., Lambrecht, A., and Guérout, R.

Subjects

Quantum Physics, Condensed Matter - Quantum Gases, Physics - Atomic Physics

Abstract

We study the energy spectrum of atoms trapped in a vertical 1D optical lattice in close proximity to a reflective surface. We propose an effective model to describe the interaction between the atoms and the surface at any distance. Our model includes the long-range Casimir-Polder potential together with a short-range Lennard-Jones potential, which are considered non-perturbatively with respect to the optical lattice potential. We find an intricate energy spectrum which contains a pair of loosely-bound states localized close to the surface in addition to a surface-modified Wannier-Stark ladder at long distances. Atomic interferometry involving those loosely-bound atom-surface states is proposed to probe the adsorption dynamics of atoms on mirrors.

Published

2016

8. Reply to the Comment on 'The Lifshitz-Matsubara sum formula for the Casimir pressure between magnetic metallic mirrors'

Author

Guérout, R, Lambrecht, A, Milton, K A, and Reynaud, S

Subjects

Quantum Physics

Abstract

We reply to the "Comment on 'The Lifshitz-Matsubara sum formula for the Casimir pressure between magnetic metallic mirrors'" [arXiv:1604.06432]. We believe the comment misrepresents our papers, and fails to provide a plausible resolution to the conflict between theory and experiment., Comment: To appear in Phys. Rev. E

Published

2016

9. The Lifshitz-Matsubara sum formula for the Casimir pressure between magnetic metallic mirrors

Author

Guerout, R., Lambrecht, A., Milton, K. A., and Reynaud, S.

Subjects

Quantum Physics

Abstract

We examine the conditions of validity for the Lifshitz-Matsubara sum formula for the Casimir pressure between magnetic metallic plane mirrors. As in the previously studied case of non-magnetic materials (Guerout et al, Phys. Rev. E 90 042125), we recover the usual expression for the lossy model of optical response, but not for the lossless plasma model. We also show that the modes associated with the Foucault currents play a crucial role in the limit of vanishing losses, in contrast to expectations.

Published

2015

10. Casimir torque between nanostructured plates

Author

Guérout, R., Genet, C., Lambrecht, A., and Reynaud, S.

Subjects

Quantum Physics

Abstract

We investigate in detail the Casimir torque induced by quantum vacuum fluctuations between two nanostructured plates. Our calculations are based on the scattering approach and take into account the coupling between different modes induced by the shape of the surface which are neglected in any sort of proximity approximation or effective medium approach. We then present an experimental setup aiming at measuring this torque., Comment: 7 pages, 7 figures

Published

2015

11. Casimir-Polder induced Rabi oscillations

Author

Donaire, M., Gorza, M. -P., Maury, A., Guerout, R., and Lambrecht, A.

Subjects

Quantum Physics

Abstract

We show that the Casimir-Polder interaction may induce coherent oscillations between degenerate atomic states. We illustrate this effect by computing the Casimir-Polder induced Rabi frequency on a $^{87}$Rb atom as it interacts with a reflecting surface. The atom oscillates between two Zeeman sublevels of its ground state undergoing a periodic exchange of angular momentum with the vacuum photons., Comment: minor corrections made to agree with the published version

Published

2014

12. Derivation of the Lifshitz-Matsubara sum formula for the Casimir pressure between metallic plane mirrors

Author

Guérout, R., Lambrecht, A., Milton, K. A., and Reynaud, S.

Subjects

Quantum Physics

Abstract

We carefully re-examine the conditions of validity for the consistent derivation of the Lifshitz-Matsubara sum formula for the Casimir pressure between metallic plane mirrors. We recover the usual expression for the lossy Drude model, but not for the lossless plasma model. We give an interpretation of this new result in terms of the modes associated with the Foucault currents which play a role in the limit of vanishing losses, in contrast to common expectations., Comment: Accepted in Phys. Rev. E

Published

2014

13. Quantum reflection of antihydrogen from Casimir potential above matter slabs

Author

Dufour, G., Gérardin, A., Guérout, R., Lambrecht, A., Nesvizhevsky, V. V., Reynaud, S., and Voronin, A. Yu.

Subjects

Quantum Physics, Condensed Matter - Other Condensed Matter

Abstract

We study quantum reflection of antihydrogen atoms from matter slabs due to the van der Waals/Casimir-Polder (vdW/CP) potential. By taking into account the specificities of antihydrogen and the optical properties and width of the slabs we calculate realistic estimates for the potential and quantum reflection amplitudes. Next we discuss the paradoxical result of larger reflection coefficients estimated for weaker potentials in terms of the Schwarzian derivative. We analyze the limiting case of reflections at small energies, which are characterized by a scattering length and have interesting applications for trapping and guiding antihydrogen using material walls.

Published

2012

14. Quantum reflection of antihydrogen from nanoporous media

Author

Dufour, G., Guérout, R., Lambrecht, A., Nesvizhevsky, V. V., Reynaud, S., and Voronin, A. Yu.

Subjects

Physics - Atomic Physics, Quantum Physics

Abstract

We study quantum reflection of antihydrogen atoms from nanoporous media due to the Casimir-Polder (CP) potential. Using a simple effective medium model, we show a dramatic increase of the probability of quantum reflection of antihydrogen atoms if the porosity of the medium increases. We discuss the limiting case of reflections at small energies, which have interesting applications for trapping and guiding antihydrogen using material walls.

Published

2012

15. Thermal Casimir force between nanostructured surfaces

Author

Guérout, R., Lussange, J., Chan, H. B., Lambrecht, A., and Reynaud, S.

Subjects

Quantum Physics, Condensed Matter - Other Condensed Matter

Abstract

We present detailed calculations for the Casimir force between a plane and a nanostructured surface at finite temperature in the framework of the scattering theory. We then study numerically the effect of finite temperature as a function of the grating parameters and the separation distance. We also infer non-trivial geometrical effects on the Casimir interaction via a comparison with the proximity force approximation. Finally, we compare our calculations with data from experiments performed with nanostructured surfaces.

Published

2012

16. Radiative heat transfer between two dielectric nanogratings in the scattering approach

Author

Lussange, J., Guérout, R., Rosa, F. S. S., Greffet, J. -J., Lambrecht, A., and Reynaud, S.

Subjects

Quantum Physics, Condensed Matter - Other Condensed Matter

Abstract

We present a theoretical study of radiative heat transfer between dielectric nanogratings in the scattering approach. As a comparision with these exact results, we also evaluate the domain of validity of Derjaguin's Proximity Approximation (PA). We consider a system of two corrugated silica plates with various grating geometries, separation distances, and lateral displacement of the plates with respect to one another. Numerical computations show that while the PA is a good approximation for aligned gratings, it cannot be used when the gratings are laterally displaced. We illustrate this by a thermal modulator device for nanosystems based on such a displacement.

Published

2012

17. Enhanced radiative heat transfer between nanostructured gold plates

Author

Guérout, R., Lussange, J., Rosa, F. S. S., Hugonin, J. -P., Dalvit, D. A. R., Greffet, J. -J., Lambrecht, A., and Reynaud, S.

Subjects

Physics - Optics, Quantum Physics

Abstract

We compute the radiative heat transfer between nanostructured gold plates in the framework of the scattering theory. We predict an enhancement of the heat transfer as we increase the depth of the corrugations while keeping the distance of closest approach fixed. We interpret this effect in terms of the evolution of plasmonic and guided modes as a function of the grating's geometry.

Published

2012

18. The Casimir force on a surface with shallow nanoscale corrugations: Geometry and finite conductivity effects

Author

Bao, Y., Guérout, R., Lussange, J., Lambrecht, A., Cirelli, R. A., Klemens, F., Mansfield, W. M., Pai, C. S., and Chan, H. B.

Subjects

Quantum Physics

Abstract

We measure the Casimir force between a gold sphere and a silicon plate with nanoscale, rectangular corrugations with depth comparable to the separation between the surfaces. In the proximity force approximation (PFA), both the top and bottom surfaces of the corrugations contribute to the force, leading to a distance dependence that is distinct from a flat surface. The measured Casimir force is found to deviate from the PFA by up to 15%, in good agreement with calculations based on scattering theory that includes both geometry effects and the optical properties of the material.

Published

2010

19. Potential energy and dipole moment surfaces of H3- molecule

Author

Ayouz, M., Dulieu, O., Guerout, R., Robert, J., and Kokoouline, V.

Subjects

Physics - Atomic Physics, Physics - Chemical Physics

Abstract

A new potential energy surface for the electronic ground state of the simplest triatomic anion H3- is determined for a large number of geometries. Its accuracy is improved at short and large distances compared to previous studies. The permanent dipole moment surface of the state is also computed for the first time. Nine vibrational levels of H3- and fourteen levels of D3- are obtained, bound by at most ~70 cm^{-1} and ~ 126 cm^{-1} respectively. These results should guide the spectroscopic search of the H3- ion in cold gases (below 100K) of molecular hydrogen in the presence of H3- ions.

Published

2010

20. Formation of the simplest stable negative molecular ion H3- in interstellar medium

Author

Kokoouline, V., Ayouz, M., Guerout, R., Raoult, M., Robert, J., and Dulieu, O.

Subjects

Physics - Atomic Physics, Physics - Plasma Physics

Abstract

We present the theory of radiative association of atoms and molecules, and we apply it to the (H$_2$-H$^-$) van der Waals complex. We discuss the possibility for the H$_3^-$ ion to be formed in the interstellar medium in an environment with abundant ionized molecular hydrogen H$_2^+$. The observation of H$_3^-$ would also be a probe for the presence of H$^-$ in the interstellar medium. By computing the electronic structure of the H$_3^-$ ion, we determine its dipole moment, bound states, rotational constants, predissociated vibrational resonances and their lifetimes, and suggest a way to detect the ion in the interstellar medium.

Published

2009