Your search keyword '"Cortese, Erika"' showing total 31 results

1. An engineered planar plasmonic reflector for polaritonic mode confinement

Author

Rajabali, Shima, Enkner, Josefine, Cortese, Erika, Beck, Mattias, De Liberato, Simone, Faist, Jérôme, and Scalari, Giacomo

Subjects

Condensed Matter - Mesoscale and Nanoscale Physics, Physics - Optics

Abstract

It was recently demonstrated that, in deep subwavelength gap resonators coupled to two-dimensional electron gases, coupling to propagating plasmons can lead to energy leakage and prevent the formation of polaritonic resonances. This process, akin to Landau damping, limits the achievable field confinement and thus the value of light-matter coupling strength. In this work, we show how plasmonic subwavelength reflectors can be used to create an artificial energy stopband in the plasmon dispersion, confining them and enabling the recovery of the polaritonic resonances. Using this approach we demonstrate a normalized light-matter coupling ratio of {\Omega}/{\omega} = 0.35 employing a single quantum well with a gap size of {\lambda}/2400 in vacuum., Comment: 13 pages, 3 figures

Published

2022

2. Positronium density measurements using polaritonic effects

Author

Cortese, Erika, Cassidy, David B., and De Liberato, Simone

Subjects

Physics - Atomic Physics, Physics - Optics, Quantum Physics

Abstract

Recent experimental advances in Positronium (Ps) physics have made it possible to produce dense Ps ensembles in which Ps-Ps interactions may occur, leading to the production of Ps$_2$ molecules and paving the way to the realization of a Ps Bose-Einstein Condensate (BEC). In order to achieve this latter goal it would be advantageous to develop new methods to measure Ps densities in real-time. Here we describe a possible approach to do this using polaritonic methods: using realistic experimental parameters we demonstrate that a dense Ps gas can be strongly coupled to the photonic field of a distributed Bragg reflector microcavity. In this strongly coupled regime, the optical spectrum of the system is composed of two hybrid positronium-polariton resonances separated by the vacuum Rabi splitting, which is proportional to the square root of the Ps density. Given that polaritons can be created on a sub-cycle timescale, a spectroscopic measurement of the vacuum Rabi splitting could be used as an ultra-fast Ps density measurement in regimes relevant to Ps BEC formation. Moreover, we show how positronium-polaritons could potentially enter the ultrastrong light-matter coupling regime, introducing a radically novel platform to explore its non-perturbative phenomenology., Comment: 8 pages, 4 figures

Published

2022

3. Perspective on real-space nanophotonic field manipulation using non-perturbative light-matter coupling

Author

Cortese, Erika, Mornhinweg, Joshua, Huber, Rupert, Lange, Christoph, and De Liberato, Simone

Subjects

Physics - Optics, Condensed Matter - Mesoscale and Nanoscale Physics, Quantum Physics

Abstract

The achievement of large values of the light-matter coupling in nanoengineered photonic structures can lead to multiple photonic resonances contributing to the final properties of the same hybrid polariton mode. We develop a general theory describing multi-mode light-matter coupling in systems of reduced dimensionality and we explore their novel phenomenology, validating the predictions of our theory against numerical electromagnetic simulations. On the one hand, we characterise the spectral features linked with the multi-mode nature of the polaritons. On the other hand, we show how the interference between different photonic resonances can modify the real-space shape of the electromagnetic field associated with each polariton mode. We argue that the possibility of engineering nanophotonic resonators to maximise the multi-mode mixing, and to alter the polariton modes via applied external fields, could allow for the dynamical real-space tailoring of subwavelength electromagnetic fields., Comment: 9 pages, 6 figures

Published

2022

4. Exact solution of polaritonic systems with arbitrary light and matter frequency-dependent losses

Author

Cortese, Erika and De Liberato, Simone

Subjects

Condensed Matter - Mesoscale and Nanoscale Physics

Abstract

In this paper we perform the exact diagonalization of a light-matter strongly coupled system taking into account arbitrary losses via both energy dissipation in the optically active material and photon escape out of the resonator. This allows to naturally treat the cases of couplings with structured reservoirs, which can strongly impact the polaritonic response via frequency-dependent losses or discrete-to-continuum strong coupling. We discuss the emergent gauge freedom of the resulting theory and provide analytical expressions for all the gauge-invariant observables both in the Power-Zienau-Woolley and the Coulomb representations. In order to exemplify the results the theory is finally specialised to two specific cases. In the first one both light and matter resonances are characterised by Lorentzian linewidths, and in the second one a fixed absorption band is also present. The analytical expressions provided in this paper can be used to predict, fit, and interpret results from polaritonic experiments with arbitrary values of the light-matter coupling and with losses of arbitrary intensity and spectral shape, in both the light and matter channels.

Published

2021

5. Sculpting ultrastrong light–matter coupling through spatial matter structuring

Author

Mornhinweg Joshua, Diebel Laura, Halbhuber Maike, Riepl Josef, Cortese Erika, De Liberato Simone, Bougeard Dominique, Huber Rupert, and Lange Christoph

Subjects

cavity-qed, thz metasurfaces, multi-mode coupling, polaritonic control, Physics, QC1-999

Abstract

The central theme of cavity quantum electrodynamics is the coupling of a single optical mode with a single matter excitation, leading to a doublet of cavity polaritons which govern the optical properties of the coupled structure. Especially in the ultrastrong coupling regime, where the ratio of the vacuum Rabi frequency and the quasi-resonant carrier frequency of light, ΩR/ω c, approaches unity, the polariton doublet bridges a large spectral bandwidth 2ΩR, and further interactions with off-resonant light and matter modes may occur. The resulting multi-mode coupling has recently attracted attention owing to the additional degrees of freedom for designing light–matter coupled resonances, despite added complexity. Here, we experimentally implement a novel strategy to sculpt ultrastrong multi-mode coupling by tailoring the spatial overlap of multiple modes of planar metallic THz resonators and the cyclotron resonances of Landau-quantized two-dimensional electrons, on subwavelength scales. We show that similarly to the selection rules of classical optics, this allows us to suppress or enhance certain coupling pathways and to control the number of light–matter coupled modes, their octave-spanning frequency spectra, and their response to magnetic tuning. This offers novel pathways for controlling dissipation, tailoring quantum light sources, nonlinearities, correlations as well as entanglement in quantum information processing.

Published

2024

6. Polaritonic non-locality in ultrastrong light-matter coupling

Author

Rajabali, Shima, Cortese, Erika, Beck, Mattias, De Liberato, Simone, Faist, Jérôme, and Scalari, Giacomo

Subjects

Condensed Matter - Mesoscale and Nanoscale Physics, Physics - Optics

Abstract

Sub-wavelength electromagnetic field localization has been central in photonic research in the last decade, allowing to enhance sensing capabilities as well as increasing the coupling between photons and material excitations. The ultrastrong light-matter coupling regime in the THz range with split-ring resonators coupled to magnetoplasmons has been widely investigated, achieving successive world-records for the largest light-matter coupling ever achieved. Ever shrinking resonators have allowed to approach the regime of few electrons strong coupling, in which single-dipole properties can be modified by the vacuum field. Here we demonstrate, theoretically and experimentally, the existence of a limit to the possibility of arbitrarily increasing electromagnetic confinement in polaritonic systems. Strongly sub-wavelength fields can excite a continuum of high-momenta propagative magnetoplasmons. This leads to peculiar nonlocal polaritonic effects, as certain polaritonic features disappear and the system enters in the regime of bound-to-continuum strong coupling. Emerging nonlinearities due to the local breaking of Kohn's theorem are also reported., Comment: 24 pages, 4 figures

Published

2021

7. Excitons bound by photon exchange

Author

Cortese, Erika, Tran, Linh, Manceau, Jean-Michel, Bousseksou, Adel, Carusotto, Iacopo, Biasiol, Giorgio, Colombelli, Raffaele, and De Liberato, Simone

Subjects

Condensed Matter - Mesoscale and Nanoscale Physics, Condensed Matter - Strongly Correlated Electrons, Quantum Physics

Abstract

In contrast to interband excitons in undoped quantum wells, doped quantum wells do not display sharp resonances due to excitonic bound states. In these systems the effective Coulomb interaction between electrons and holes typically only leads to a depolarization shift of the single-electron intersubband transitions. Non-perturbative light-matter interaction in solid-state devices has been investigated as a pathway to tune optoelectronic properties of materials. A recent theoretical work [Cortese et al., Optica 6, 354 (2019)] predicted that, when the doped quantum wells are embedded in a photonic cavity, emission-reabsorption processes of cavity photons can generate an effective attractive interaction which binds electrons and holes together, leading to the creation of an intraband bound exciton. Spectroscopically, this bound state manifests itself as a novel discrete resonance which appears below the ionisation threshold only when the coupling between light and matter is increased above a critical value. Here we report the first experimental observation of such a bound state using doped GaAs/AlGaAs quantum wells embedded in metal-metal resonators whose confinement is high enough to permit operation in strong coupling. Our result provides the first evidence of bound states of charged particles kept together not by Coulomb interaction, but by the exchange of transverse photons. Light-matter coupling can thus be used as a novel tool in quantum material engineering, tuning electronic properties of semiconductor heterostructures beyond those permitted by mere crystal structures, with direct applications to mid-infrared optoelectronics.

Published

2019

8. Tuning materials' properties by non-perturbative cavity quantum electrodynamics

Author

Cortese, Erika and De Liberato, Simone

Abstract

When in a quantum optical system the coupling between matter and cavity mode becomes comparable to the bare excitation frequency, we enter a non-perturbative coupling regime, as perturbation theory fails describing the system's dynamics. While recent advances in Cavity Quantum Electrodynamics allowed to achieve very high values of the coupling strength, thanks to the resonators properties optimization and the employment of solid-state devices, an ever growing interest has been shown about the possibility of significantly modify materials' properties. It has been demonstrated that the chemical structure of molecules strongly coupled to a photon mode can be altered, which opens the possibility to manipulate and control chemical reactions. The aim of this thesis is to explore non-perturbative regimes on several quantum systems, and to investigate the effects of the coupling upon their properties, such as internal degrees of freedom or electronic states structure. I first developed a novel theory to determine the polariton spectrum of a dipolar ensamble in which a Ising-like dipole-dipole interaction in the 2 non-perturbative regime is considered. A further important focus is the investigation of the saturation effects due to the inclusion of the inter-dipole interaction, and the interplay between the latter and light-matter coupling strength. I also explored specifically the influence of the coupling on the rotational degrees of freedom of an ensemble of two-dimensional freely rotating dipoles, all coupled to a single cavity mode, finding that they are driven by the collective light-matter coupling to undergo a crossover between an isotropic and an aligned phase. I then investigated the case of cavity-embedded doped quantum wells, demonstrating that not only it is possible to couple a discrete cavity mode and bound-to-continuum transitions, but also that a novel bound exciton state appears, induced by the coupling strength. This results shows how light-matter coupling can be used to tune both optical and electronic properties of semiconductor heterostructures beyond those permitted by mere crystal properties. Finally, I explored the physics of an array of THz metamaterial resonators coupled to cyclotron resonances of a two-dimensional electron gas, developing a multiple-mode theory that takes in account the interaction between multiple photon modes mediated by the electrons. My results show that this cross-interaction, due to the strong two-dimensional geometry of the optically active medium, leads to the hybridization of different uncoupled photon modes, and manifests as a visible change of the distribution of the coupled electromagnetic field.

Published

2020

9. Strong coupling of ionising transitions

Author

Cortese, Erika, Carusotto, Iacopo, Colombelli, Raffaele, and De Liberato, Simone

Subjects

Physics - Optics, Condensed Matter - Mesoscale and Nanoscale Physics, Quantum Physics

Abstract

We demonstrate that a ionising transition can be strongly coupled to a photonic resonance. The strong coupling manifests itself with the appearance of a narrow optically active resonance below the ionisation threshold. Such a resonance is due to electrons transitioning into a novel bound state created by the collective coupling of the electron gas with the vacuum field of the photonic resonator. Applying our theory to the case of bound-to-continuum transitions in microcavity-embedded doped quantum wells, we show how those strong-coupling features can be exploited as a novel knob to tune both optical and electronic properties of semiconductor heterostructures., Comment: 10 pages, 7 figures

Published

2018

10. Polariton spectrum of the Dicke-Ising model

Author

Cortese, Erika, Garziano, Luigi, and De Liberato, Simone

Subjects

Quantum Physics

Abstract

The Dicke-Ising model describes cavity quantum electrodynamics setups in which dipoles couple not only with the photonic cavity field but also to each other through dipole-dipole interaction. In this work we diagonalise such a model in terms of bosonic polaritonic operators for arbitrarily large values of the light-matter coupling and for values of the dipole-dipole interaction until the onset of the ferromagnetic Ising phase transition. In order to accomplish this task we exploit higher order terms of the Holstein-Primakoff transformation, developing a general method which allows to solve the normal phase of the Ising model in term of bosonic excitations for large values of the dipole-dipole interaction. Our results shed light on the interplay between the dipole-dipole and the light-matter coupling strengths, and their effect on the virtual excitations which populate the ground-state when the interactions become comparable with the bare transition frequency., Comment: 13 pages, 6 figures

Published

2017

11. Collective optomechanical effects in cavity quantum electrodynamics

Author

Cortese, Erika, Lagoudakis, Pavlos, and De Liberato, Simone

Subjects

Quantum Physics, Condensed Matter - Mesoscale and Nanoscale Physics

Abstract

We investigate a cavity quantum electrodynamic effect, where the alignment of two-dimensional freely rotating optical dipoles is driven by their collective coupling to the cavity field. By exploiting the formal equivalence of a set of rotating dipoles with a polymer we calculate the partition function of the coupled light-matter system and demonstrate it exhibits a second order phase transition between a bunched state of isotropic orientations and a stretched one with all the dipoles aligned. Such a transition manifests itself as an intensity-dependent shift of the polariton mode resonance. Our work, lying at the crossroad between cavity quantum electrodynamics and quantum optomechanics, is a step forward in the on-going quest to understand how strong coupling can be exploited to influence matter internal degrees of freedom., Comment: 6 pages, 3 figures

Published

2017

12. An engineered planar plasmonic reflector forpolaritonic mode confinement

Author

Rajabali, Shima, primary, Enkner, Josefine, additional, Cortese, Erika, additional, Beck, Mattias, additional, De Liberato, Simone, additional, Faist, Jérôme, additional, and Scalari, Giacomo, additional

Published

2023

13. Non-locality and single meta-atom spectroscopy in THz Landau polaritons

Author

Scalari Giacomo, Rajabali Shima, Jöchl Elsa, Markmann Sergej, de Liberato Simone, Cortese Erika, Beck Mattias, and Faist Jérôme

Subjects

Physics, QC1-999

Abstract

We will discuss, theoretically and experimentally, the existence of a limit to the possibility of arbitrarily increasing electromagnetic confinement in polaritonic systems, where strongly sub-wavelength fields can excite a continuum of high-momenta propagative magnetoplasmons. This leads to peculiar nonlocal polaritonic effects, as certain polaritonic features disappear and the system enters in the regime of discrete-to-continuum strong coupling. We will as well present experiments reporting spectroscopy of a single, ultrastrongly coupled, highly subwavelength resonator operating at 300 GHz.

Published

2022

14. Exact solution of polaritonic systems with arbitrary light and matter frequency-dependent losses.

Author

Cortese, Erika and De Liberato, Simone

Subjects

RADIANT intensity, ENERGY dissipation, RESONATORS

Abstract

In this paper, we perform the exact diagonalization of a light–matter strongly coupled system taking into account arbitrary losses via both energy dissipation in the optically active material and photon escape out of the resonator. This allows us to naturally treat the cases of couplings with structured reservoirs, which can strongly impact the polaritonic response via frequency-dependent losses or discrete-to-continuum strong coupling. We discuss the emergent gauge freedom of the resulting theory and provide analytical expressions for all the gauge-invariant observables in both the Power–Zienau–Woolley and the Coulomb representations. In order to exemplify the results, the theory is finally specialized to two specific cases. In the first one, both light and matter resonances are characterized by Lorentzian linewidths, and in the second one, a fixed absorption band is also present. The analytical expressions derived in this paper can be used to predict, fit, and interpret results from polaritonic experiments with arbitrary values of the light–matter coupling and with losses of arbitrary intensity and spectral shape in both the light and matter channels. A Matlab code implementing our results is provided. [ABSTRACT FROM AUTHOR]

Published

2022

15. Positronium density measurements using polaritonic effects

Author

Cortese, Erika, primary, Cassidy, David B., additional, and De Liberato, Simone, additional

Published

2023

16. Real-space nanophotonic field manipulation using non-perturbative light–matter coupling

Author

Cortese, Erika, primary, Mornhinweg, Joshua, additional, Huber, Rupert, additional, Lange, Christoph, additional, and De Liberato, Simone, additional

Published

2022

17. Real-space nanophotonic field manipulation using Landau polaritons

Author

Cortese, Erika, primary, Mornhinweg, Joshua, additional, Lange, Christoph, additional, and De Liberato, Simone, additional

Published

2022

18. Breakdown of Polaritons in Nanophotonic Systems

Author

Rajabali, Shima, primary, Cortese, Erika, additional, Beck, Mattias, additional, Liberato, Simone De, additional, Faist, Jerome, additional, and Scalari, Giacomo, additional

Published

2021

19. Polaritonic nonlocality in light–matter interaction

Author

Rajabali, Shima, primary, Cortese, Erika, additional, Beck, Mattias, additional, De Liberato, Simone, additional, Faist, Jérôme, additional, and Scalari, Giacomo, additional

Published

2021

20. Breakdown of polaritons in ultrastrongly coupled nanophotonic systems

Author

Rajabali, Shima, primary, Cortese, Erika, additional, Beck, Mattias, additional, De Liberato, Simone, additional, Faist, Jerome, additional, and Scalari, Giacomo, additional

Published

2021

21. Bound-to-continuum Non-perturbative Regime for an Ultrastong Light-matter Coupling

Author

Rajabali, Shima, primary, Cortese, Erika, additional, Beck, Mattias, additional, De Liberato, Simone, additional, Faist, Jérôme, additional, and Scalari, Giacomo, additional

Published

2021

22. Oservation of bound excitons stabilised by the interaction with a photonic resonator

Author

Cortese, Erika, primary, Tran, Ngoc Linh, additional, Manceau, Jean-Michel, additional, Bousseksou, Adel, additional, Carusotto, Iacopo, additional, Biasiol, Giorgio, additional, Colombelli, Raffaele, additional, and De Liberato, Simone, additional

Published

2021

23. Excitons bound by photon exchange

Author

Cortese, Erika, primary, Tran, Ngoc-Linh, additional, Manceau, Jean-Michel, additional, Bousseksou, Adel, additional, Carusotto, Iacopo, additional, Biasiol, Giorgio, additional, Colombelli, Raffaele, additional, and De Liberato, Simone, additional

Published

2020

24. Tuning materials' properties by non-perturbative cavity quantum electrodynamics

Author

Cortese, Erika. and Cortese, Erika.

Abstract

When in a quantum optical system the coupling between matter and cavity mode becomes comparable to the bare excitation frequency, we enter a non-perturbative coupling regime, as perturbation theory fails describing the system’s dynamics. While recent advances in Cavity Quantum Electrodynamics allowed to achieve very high values of the coupling strength, thanks to the resonators properties optimization and the employment of solid-state devices, an ever growing interest has been shown about the possibility of significantly modify materials’ properties. It has been demonstrated that the chemical structure of molecules strongly coupled to a photon mode can be altered, which opens the possibility to manipulate and control chemical reactions. The aim of this thesis is to explore non-perturbative regimes on several quantum systems, and to investigate the effects of the coupling upon their properties, such as internal degrees of freedom or electronic states structure. I first developed a novel theory to determine the polariton spectrum of a dipolar ensamble in which a Ising-like dipole-dipole interaction in the 2 non-perturbative regime is considered. A further important focus is the investigation of the saturation effects due to the inclusion of the inter-dipole interaction, and the interplay between the latter and light-matter coupling strength. I also explored specifically the influence of the coupling on the rotational degrees of freedom of an ensemble of two-dimensional freely rotating dipoles, all coupled to a single cavity mode, finding that they are driven by the collective light-matter coupling to undergo a crossover between an isotropic and an aligned phase. I then investigated the case of cavity-embedded doped quantum wells, demonstrating that not only it is possible to couple a discrete cavity mode and bound-to-continuum transitions, but also that a novel bound exciton state appears, induced by the coupling strength. This results shows how light–matter

Published

2020

25. Strong coupling of ionizing transitions

Author

Cortese, Erika, primary, Carusotto, Iacopo, additional, Colombelli, Raffaele, additional, and De Liberato, Simone, additional

Published

2019

26. Polariton spectrum of the Dicke-Ising model

Author

Cortese, Erika, primary, Garziano, Luigi, additional, and De Liberato, Simone, additional

Published

2017

27. Publisher’s Note: Collective Optomechanical Effects in Cavity Quantum Electrodynamics [Phys. Rev. Lett. 119 , 043604 (2017)]

Author

Cortese, Erika, primary, Lagoudakis, Pavlos G., additional, and De Liberato, Simone, additional

Published

2017

28. Collective Optomechanical Effects in Cavity Quantum Electrodynamics

Author

Cortese, Erika, primary, Lagoudakis, Pavlos G., additional, and De Liberato, Simone, additional

Published

2017

29. Excitons bound by photon exchange

Author

Cortese, Erika, Tran, Ngoc-Linh, Manceau, Jean-Michel, Bousseksou, Adel, Carusotto, Iacopo, Biasiol, Giorgio, Colombelli, Raffaele, and De Liberato, Simone

Abstract

In contrast to interband excitons in undoped quantum wells, doped quantum wells do not display sharp resonances due to excitonic bound states. The effective Coulomb interaction between electrons and holes in these systems typically leads to only a depolarization shift of the single-electron intersubband transitions1. Non-perturbative light–matter interaction in solid-state devices has been investigated as a pathway to tuning optoelectronic properties of materials2,3. A recent theoretical work4predicted that when the doped quantum wells are embedded in a photonic cavity, emission–reabsorption processes of cavity photons can generate an effective attractive interaction that binds electrons and holes together, leading to the creation of an intraband bound exciton. Here, we spectroscopically observe such a bound state as a discrete resonance that appears below the ionization threshold only when the coupling between light and matter is increased above a critical value. Our result demonstrates that two charged particles can be bound by the exchange of transverse photons. Light–matter coupling can thus be used as a tool in quantum material engineering, tuning electronic properties of semiconductor heterostructures beyond those permitted by mere crystal structures, with direct applications to mid-infrared optoelectronics.

Published

2021

30. 3803541.pdf

Author

Cortese, Erika, Carusotto, Iacopo, Colombelli, Raffaele, and De Liberato, Simone

Subjects

3. Good health

Abstract

This document provides supplementary information to "Strong coupling of ionising transitions", including explicit derivations of the theoretical results presented in the main paper.

31. 3803541.pdf

Author

Cortese, Erika, Carusotto, Iacopo, Colombelli, Raffaele, and De Liberato, Simone

Subjects

3. Good health

Abstract

This document provides supplementary information to "Strong coupling of ionising transitions", including explicit derivations of the theoretical results presented in the main paper.