Your search keyword '"Rocca G"' showing total 20 results

1. Single-photon manipulations based on optically-controlled chiral couplings in waveguide structures of Rydberg giant atoms

Author

Chen, Yao-Tong, Du, Lei, Wang, Zhihai, Artoni, M., La Rocca, G. C., and Wu, Jin-Hui

Subjects

Quantum Physics

Abstract

Two interacting Rydberg atoms coupled to a waveguide realize a giant-atom platform that exhibits the controllable (phase-dependent) chirality where the direction of nonreciprocal photon scattering can be switched on demand, e.g., by the geometrical tuning of an external driving field. At variance with previous chiral setups, the simplified approach of our proposed platform arises from an optical implementation of the local phase difference between two coupling points of the Rydberg giant atom. Furthermore, employing two or more driving fields, this platform could also be used as a frequency converter with its efficiency exhibiting a strong asymmetry and being significantly enhanced via the chiral couplings. Our results suggest an extendable giant-atom platform that is both innovative and promising for chiral quantum optics and tunable frequency conversion in the optical domain.

Published

2023

2. Giant-Atom Effects on Population and Entanglement Dynamics of Rydberg Atoms

Author

Chen, Yao-Tong, Du, Lei, Zhang, Yan, Guo, Lingzhen, Wu, Jin-Hui, Artoni, M., and La Rocca, G. C.

Subjects

Quantum Physics

Abstract

Giant atoms are attracting interest as an emerging paradigm in the quantum optics of engineered waveguides. Here we propose to realize a synthetic giant atom working in the optical regime starting from a pair of interacting Rydberg atoms driven by a coherent field and coupled to a photonic crystal waveguide. Giant-atom effects can be observed as a phase-dependent decay of the double Rydberg excitation during the initial evolution of this atomic pair while (internal) atomic entanglement is exhibited at later times. Such an intriguing entanglement onset occurs in the presence of intrinsic atomic decay toward non-guided vacuum modes and is accompanied by an anti-bunching correlation of the emitted photons. Our findings may be relevant to quantum information processing, besides broadening the giant-atom waveguide physics with optically driven natural atoms., Comment: 12 pages, 5 figures

Published

2023

3. The Cypress Canker Disease Pandemic

Author

Scali, E., Garbelotto, M., Danti, R., and Della Rocca, G.

Published

2025

4. Quantum transport in nonlinear Rudner-Levitov models

Author

Du, Lei, Wu, Jin-Hui, Artoni, M., and La Rocca, G. C.

Subjects

Quantum Physics

Abstract

Quantum transport in a class of nonlinear extensions of the Rudner-Levitov model is numerically studied in this paper. We show that the quantization of the mean displacement, which embodies the quantum coherence and the topological characteristics of the model, is markedly modified by nonlinearities. Peculiar effects such as a "trivial-nontrivial" transition and unidirectional long-range quantum transport are observed. These phenomena can be understood on the basis of the dynamic behavior of the effective hopping terms, which are time and position dependent, containing contributions of both the linear and nonlinear couplings.d nonlinear couplings., Comment: 8 pages, 7 figures

Published

2021

5. Spatial Kramers-Kronig relation and controlled unidirectional reflection in cold atoms

Author

Zhang, Yan, Wu, Jin-Hui, Artoni, M., and La Rocca, G. C.

Subjects

Quantum Physics, Physics - Atomic Physics, Physics - Optics

Abstract

We propose a model for realizing frequency-dependent spatial variations of the probe susceptibility in a cold atomic sample. It is found that the usual Kramers-Kronig (KK) relation between real and imaginary parts of the probe susceptibility in the frequency domain can be mapped into the space domain as a far detuned control field of intensity linearly varied in space is used. This non-Hermitian medium exhibits then a unidirectional reflectionless frequency band for probe photons incident from either the left or the right sample end. It is of special interest that we can tune the frequency band as well as choose the direction corresponding to the vanishing reflectivity by changing, respectively, the control field intensity and frequency. The nonzero reflectivity from the other direction is typically small for realistic atomic densities, but can be largely enhanced by incorporating the Bragg scattering into the spatial KK relation so as to achieve a high reflectivity contrast.

Published

2020

6. Discrete time crystal in a finite chain of Rydberg atoms without disorder

Author

Fan, Chuhui, Rossini, D., Zhang, Han-Xiao, Wu, Jin-Hui, Artoni, M., and La Rocca, G. C.

Subjects

Quantum Physics, Physics - Atomic Physics

Abstract

We study the collective dynamics of a clean Floquet system of cold atoms, numerically simulating two realistic set-ups based on a regular chain of interacting Rydberg atoms driven by laser fields. In both cases, the population evolution and its Fourier spectrum display clear signatures of a discrete time crystal (DTC), exhibiting the appearance of a robust subharmonic oscillation which persists on a time scale increasing with the chain size, within a certain range of control parameters. We also characterize how the DTC stability is affected by dissipative processes, typically present in this atomic system even though the Rydberg state is very long lived.

Published

2019

7. Generation Engineering of Heralded Narrowband Colour Entangled States

Author

Zavatta, A., Artoni, M., and La Rocca, G.

Subjects

Quantum Physics

Abstract

Efficient heralded generation of entanglement together with its manipulation is of great importance for quantum communications. In addition, states generated with bandwidths naturally compatible with atomic transitions allow a more efficient mapping of light into matter which is an essential requirement for long distance quantum communications. Here we propose a scheme where the indistinguishability between two spontaneous four-wave mixing processes is engineered to herald generation of single-photon frequency-bin entangled states, i.e., single-photons shared by two distinct frequency modes. We show that entanglement can be optimised together with the generation probability, while maintaining absorption negligible. Besides, the scheme illustrated for cold rubidium atoms is versatile and can be implemented in several other physical systems.

Published

2018

8. Non-reflecting permittivity profiles and the spatial Kramers-Kronig relations

Author

Horsley, S. A. R., Artoni, M., and La Rocca, G. C.

Subjects

Physics - Optics, Mathematical Physics

Abstract

We show that if the permittivity profile of a planar dielectric medium is an analytic function in the upper (lower) half complex position plane then it won't reflect radiation from the left (right), whatever the angle of incidence. Consequently, using the spatial Kramers-Kronig relations one can derive a real part of a permittivity profile from some given imaginary part (or vice versa), such that the reflection is guaranteed to be zero. This result is valid for both scalar and vector wave theories, and may have relevance for efficiently absorbing radiation, or reducing reflection from bodies., Comment: 10 pages, 3 figures

Published

2015

9. Optical non-reciprocity of cold atom Bragg mirrors in motion

Author

Horsley, S. A. R., Wu, J. -H., Artoni, M., and La Rocca, G. C.

Subjects

Physics - Optics, Physics - Atomic Physics, Quantum Physics

Abstract

Reciprocity is fundamental to light transport and is a concept that holds also in rather complex systems. Yet, reciprocity can be switched off even in linear, isotropic and passive media by setting the material structure into motion. In highly dispersive multilayers this leads to a fairly large forward-backward asymmetry in the pulse transmission. Moreover, in multilevel systems, this transport phenomenon can be all-optically enhanced. For atomic multilayer structures made of three-level cold Rubidium 87 atoms, for instance, forward-backward transmission contrast around 95 per cent can be obtained already at atomic speeds in the meter per second range. The scheme we illustrate may open up avenues for optical isolation that were not previously accessible., Comment: 5 pages, 4 figures

Published

2013

10. Revisiting the Bragg reflector to illustrate some modern developments in optics

Author

Horsley, S. A. R., Wu, J. -H., Artoni, M., and La Rocca, G. C.

Subjects

Physics - Optics, Quantum Physics

Abstract

A series of thin layers of alternating refractive index is known to make a good optical mirror over certain bands of frequency. Such a device - often termed the Bragg reflector - is usually introduced to students within the first years of an undergraduate degree, often in isolation from other parts of the course. Here we show that the basic physics of wave propagation through a stratified medium can be used to illustrate some more modern developments in optics as well as quantum physics; from transfer matrix techniques, to the optical properties of cold trapped atoms, optomechanical cooling, and a simple example of a system exhibiting an appreciable level of optical non-reciprocity., Comment: 24 pages, 9 figures

Published

2013

11. Two-color quantum memory in double {\Lambda}-media

Author

Viscor, D., Ahufinger, V., Mompart, J., Zavatta, A., La Rocca, G. C., and Artoni, M.

Subjects

Quantum Physics

Abstract

We propose a quantum memory for a single-photon wave packet in a superposition of two different colors, i.e., two different frequency components, using the electromagnetically induced transparency technique in a double-{\Lambda} system. We examine a specific configuration in which the two frequency components are able to exchange energy through a four-wave mixing process as they propagate, so the state of the incident photon is recovered periodically at certain positions in the medium. We investigate the propagation dynamics as a function of the relative phase between the coupling beams and the input single-photon frequency components. Moreover, by considering time-dependent coupling beams, we numerically simulate the storage and retrieval of a two-frequency-component single-photon qubit., Comment: 9 pages, 5 figures

Published

2013

12. Radiation pressure, moving media, and multilayer systems

Author

Horsley, S. A. R., Artoni, M., and La Rocca, G. C.

Subjects

Physics - Optics, Quantum Physics

Abstract

A general theory of optical forces on moving bodies is here developed in terms of generalized/4x4 transfer and scattering matrices. Results are presented for a planar dielectric multilayer of arbitrary refractive index placed in an otherwise empty space and moving parallel and perpendicular to the slab-vacuum interface. In both regimes of motion the resulting force comprises lateral and normal velocity-dependent components which may depend in a subtle way on the Doppler effect and TE-TM polarization mixing. For lateral displacements in particular, polarization mixing, which is here interpreted as an effective magneto-electric effect due to the reduced symmetry induced by the motion of the slab, gives rise to a velocity dependent force contribution that is sensitive to the phase difference between the two polarization amplitudes. This term gives rise to a rather peculiar optical response on the moving body and specific caseses are illustrated for incident radiation of arbitrarily directed linear polarization. The additional force due to polarization mixing may cancel to first order in V/c with the first order Doppler contribution yielding an overall vanishing of the velocity-dependent component of the force on the body. The above findings bare some relevance to modern developments of nano-optomechanics as well as to the problem of a frictional component to the Casimir force., Comment: 14 pages, 4 figures

Published

2012

13. Role of anisotropy in the F\'orster energy transfer from a semiconductor quantum well to an organic crystalline overlayer

Author

Kawka, S. and La Rocca, G. C.

Subjects

Condensed Matter - Mesoscale and Nanoscale Physics, Condensed Matter - Materials Science, Physics - Optics

Abstract

We consider the non-radiative resonant energy transfer from a two-dimensional Wannier exciton (donor) to a Frenkel exciton of a molecular crystal overlayer (acceptor). We characterize the effect of the optical anisotropy of the organic subsystem on this process. Using realistic values of material parameters, we show that it is possible to change the transfer rate within typically a factor of two depending on the orientation of the crystalline overlayer. The resonant matching of donor and acceptor energies is also partly tunable via the organic crystal orientation., Comment: 6 pages, 8 figures

Published

2011

14. Radiation pressure on a moving body: beyond the Doppler effect

Author

Horsley, S. A. R., Artoni, M., and La Rocca, G. C.

Subjects

Physics - Optics

Abstract

The dependence of macroscopic radiation pressure on the velocity of the object being pushed is commonly attributed to the Doppler effect. This need not be the case, and here we highlight velocity dependent radiation pressure terms that have their origins in the mixing of s and p polarizations brought about by the Lorentz transformation between the lab and the material rest frame, rather than in the corresponding transformation of frequency and wavevector. The theory we develop is relevant to the nano-optomechanics of moving bodies., Comment: 5 pages, 2 figures

Published

2011

15. Cross-Phase Modulation and Population Redistribution in a Periodic Tripod Medium

Author

Slowik, K., Raczynski, A., Zaremba, J., Zielinska-Kaniasty, S., Artoni, M., and La Rocca, G. C.

Subjects

Quantum Physics

Abstract

The cross-Kerr effect is studied for two pulses propagating in an atomic medium in a tripod configuration, dressed by a strong standing wave coupling beam. Nonlinear phase shifts for both transmitted and reflected beams are calculated taking into account the redistribution of the population among the atomic levels which allows one to study the phase shifts in a wide range of pulse detunings. The influence of other parameters, e.g., the intensity of the control field and the relaxation rates, on the cross-Kerr effect is also examined in detail., Comment: 6 figures

Published

2010

16. Radiation 'damping' in atomic photonic crystals

Author

Horsley, S. A. R., Artoni, M., and La Rocca, G. C.

Subjects

Physics - Optics, Condensed Matter - Other Condensed Matter

Abstract

The force exerted on a material by an incident beam of light is dependent upon the material's velocity in the laboratory frame of reference. This velocity dependence is known to be diffcult to measure, as it is proportional to the incident optical power multiplied by the ratio of the material velocity to the speed of light. Here we show that this typically tiny effect is greatly amplified in multilayer systems composed of resonantly absorbing atoms (e.g. optically trapped 87Rb), which may exhibit ultra-narrow photonic band gaps. The amplification of the effect is shown to be three orders of magnitude greater than previous estimates for conventional photonic-band-gap materials, and significant for material velocities of a few ms/s., Comment: 5 pages, 3 figures

Published

2010

17. Exciton-phonon scattering and photo-excitation dynamics in J-aggregate microcavities

Author

Michetti, P. and La Rocca, G. C.

Subjects

Condensed Matter - Other Condensed Matter

Abstract

We have developed a model accounting for the photo-excitation dynamics and the photoluminescence of strongly coupled J-aggregate microcavities. Our model is based on a description of the J-aggregate film as a disordered Frenkel exciton system in which relaxation occurs due to the presence of a thermal bath of molecular vibrations. In a strongly coupled microcavity exciton-polaritons are formed, mixing superradiant excitons and cavity photons. The calculation of the microcavity steady-state photoluminescence, following a CW non resonant pumping, is carried out. The experimental photoluminescence intensity ratio between upper and lower polariton branches is accurately reproduced. In particular both thermal activation of the photoluminescence intensity ratio and its Rabi splitting dependence are a consequence of the bottleneck in the relaxation, occurring at the bottom of the excitonic reservoir. The effects due to radiative channels of decay of excitons and to the presence of a paritticular set of discrete optical molecular vibrations active in relaxation processes are investigared., Comment: 8 pages, 6 figures

Published

2008

18. A mathematical model for the therapy of the HIV infection

Author

Della Rocca, G., Sammartino, M., and Seta, L.

Subjects

Quantitative Biology - Populations and Evolution, Quantitative Biology - Quantitative Methods

Abstract

In this paper we consider the evolution of the HIV infection under a highly effective treatment based on a combination of RTI and/or PI drugs. This is usually modelled with a set of ODEs where the drug efficacy is a constant. In this paper we consider the treatment efficacy as a dynamic variable which evolves during the treatment. To model the dynamics of the drug efficacy we use an evolutive type assumption. The resulting set of ODEs are able to reproduce the typical pattern of the illness evolution under treatment: a period of remission, which can last several years, followed by a progressive recrudescence and a viral rebound., Comment: 13 pages, 7 figures

Published

2007

19. Coherent-potential-approximation study of excitonic absorption in orientationally disordered molecular aggregates

Author

Balagurov, D. B., La Rocca, G. C., and Agranovich, V. M.

Subjects

Condensed Matter - Disordered Systems and Neural Networks, Condensed Matter - Materials Science

Abstract

We study the dynamics of a single Frenkel exciton in a disordered molecular chain. The coherent-potential approximation (CPA) is applied to the situation when the single-molecule excitation energies as well as the transition dipole moments, both their absolute values and orientations, are random. Such model is believed to be relevant for the description of the linear optical properties of one-dimensional $J$ aggregates. We calculate the exciton density of states, the linear absorption spectra and the exciton coherence length which reveals itself in the linear optics. A detailed analysis of the low-disorder limit of the theory is presented. In particular, we derive asymptotic formulas relating the absorption linewidth and the exciton coherence length to the strength of disorder. Such expressions account simultaneously for all the above types of disorder and reduce to well-established form when no disorder in the transition dipoles is present. The theory is applied to the case of purely orientational disorder and is shown to agree well with exact numerical diagonalization., Comment: RevTeX4, 17 pages, 9 figures

Published

2003

20. Slow group velocity and Cherenkov radiation

Author

Carusotto, I., Artoni, M., La Rocca, G. C., and Bassani, F.

Subjects

Quantum Physics

Abstract

We theoretically study the effect of ultraslow group velocities on the emission of Vavilov-Cherenkov radiation in a coherently driven medium. We show that in this case the aperture of the group cone on which the intensity of the radiation peaks is much smaller than that of the usual wave cone associated with the Cherenkov coherence condition. We show that such a singular behaviour may be observed in a coherently driven ultracold atomic gas., Comment: 4 pages, 4 figures

Published

2001