Your search keyword '"Garbe, Louis"' showing total 19 results

1. The bosonic skin effect: boundary condensation in asymmetric transport

Author

Garbe, Louis, Minoguchi, Yuri, Huber, Julian, and Rabl, Peter

Subjects

Quantum Physics, Condensed Matter - Mesoscale and Nanoscale Physics, Condensed Matter - Quantum Gases, Condensed Matter - Statistical Mechanics, Mathematical Physics

Abstract

We study the incoherent transport of bosonic particles through a one dimensional lattice with different left and right hopping rates, as modelled by the asymmetric simple inclusion process (ASIP). Specifically, we show that as the current passing through this system increases, a transition occurs, which is signified by the appearance of a characteristic zigzag pattern in the stationary density profile near the boundary. In this highly unusual transport phase, the local particle distribution alternates on every site between a thermal distribution and a Bose-condensed state with broken U(1)-symmetry. Furthermore, we show that the onset of this phase is closely related to the so-called non-Hermitian skin effect and coincides with an exceptional point in the spectrum of density fluctuations. Therefore, this effect establishes a direct connection between quantum transport, non-equilibrium condensation phenomena and non-Hermitian topology, which can be probed in cold-atom experiments or in systems with long-lived photonic, polaritonic and plasmonic excitations.

Published

2023

2. Non-Gaussian superradiant transition via three-body ultrastrong coupling

Author

Minganti, Fabrizio, Garbe, Louis, Boité, Alexandre Le, and Felicetti, Simone

Subjects

Quantum Physics

Abstract

We introduce a class of quantum optical Hamiltonian characterized by three-body couplings, and propose a circuit-QED scheme based on state-of-the-art technology that implements the considered model. Unlike two-body light-matter interactions, this three-body coupling Hamiltonian is exclusively composed of terms which do not conserve the particle number. We explore the three-body ultrastrong coupling regime, showing the emergence of a superradiant phase transition which is of first order, is characterized by the breaking of a $\mathbb{Z}_2\times \mathbb{Z}_2$ symmetry and has a strongly non-Gaussian nature. Indeed, in contrast to what is observed in any two-body-coupling model, in proximity of the transition the ground state exhibits a divergent coskewness, i.e., quantum correlations that cannot be captured within semiclassical and Gaussian approximations. Furthermore, we demonstrate the robustness of our findings by including dissipative processes in the model, showing that the steady-state of the system inherits from the ground states the most prominent features of the transition., Comment: 6+7 pages, 3 figures

Published

2022

3. Exponential precision by reaching a quantum critical point

Author

Garbe, Louis, Abah, Obinna, Felicetti, Simone, and Puebla, Ricardo

Subjects

Quantum Physics, Condensed Matter - Mesoscale and Nanoscale Physics

Abstract

Quantum metrology shows that by exploiting nonclassical resources it is possible to overcome the fundamental limit of precision found for classical parameter-estimation protocols. The scaling of the quantum Fisher information -- which provides an upper bound to the achievable precision -- with respect to the protocol duration is then of primarily importance to assess its performances. In classical protocols the quantum Fisher information scales linearly with time, while typical quantum-enhanced strategies achieve a quadratic (Heisenberg) or even higher-order polynomial scalings. Here we report a protocol that is capable of surpassing the polynomial scaling, and yields an exponential advantage. Such exponential advantage is achieved by approaching, but without crossing, the critical point of a quantum phase transition of a fully-connected model in the thermodynamic limit. The exponential advantage stems from the breakdown of the adiabatic condition close to a critical point. As we demonstrate, this exponential scaling is well captured by the new bound derived in arXiv:2110.04144, which in turn allows us to obtain approximate analytical expressions for the quantum Fisher information that agree with exact numerical simulations. In addition, we discuss the limitations to the exponential scaling when considering a finite-size system as well as its robustness against decoherence effects. Hence, our findings unveil a novel quantum metrological protocol whose precision scaling goes beyond the paradigmatic Heisenberg limit with respect to the protocol duration., Comment: 12 pages, 4 figures; comments welcome!

Published

2021

4. Critical Quantum Metrology with Fully-Connected Models: From Heisenberg to Kibble-Zurek Scaling

Author

Garbe, Louis, Abah, Obinna, Felicetti, Simone, and Puebla, Ricardo

Subjects

Quantum Physics, Condensed Matter - Mesoscale and Nanoscale Physics

Abstract

Phase transitions represent a compelling tool for classical and quantum sensing applications. It has been demonstrated that quantum sensors can in principle saturate the Heisenberg scaling, the ultimate precision bound allowed by quantum mechanics, in the limit of large probe number and long measurement time. Due to the critical slowing down, the protocol duration time is of utmost relevance in critical quantum metrology. However, how the long-time limit is reached remains in general an open question. So far, only two dichotomic approaches have been considered, based on either static or dynamical properties of critical quantum systems. Here, we provide a comprehensive analysis of the scaling of the quantum Fisher information for different families of protocols that create a continuous connection between static and dynamical approaches. In particular, we consider fully-connected models, a broad class of quantum critical systems of high experimental relevance. Our analysis unveils the existence of universal precision-scaling regimes. These regimes remain valid even for finite-time protocols and finite-size systems. We also frame these results in a general theoretical perspective, by deriving a precision bound for arbitrary time-dependent quadratic Hamiltonians., Comment: 24 pages, 8 figures. Comments welcome!

Published

2021

5. Phase Transitions in Light-Matter Systems for Quantum Sensing

Author

Garbe, Louis

Subjects

Quantum Physics, Condensed Matter - Mesoscale and Nanoscale Physics

Abstract

When light and matter are weakly coupled, they can be described as two distinctive systems exchanging quanta of energy. By contrast, for very large coupling strength, the systems hybridize and form compounds that cannot be described in terms of light or matter only. In this Thesis, we study some exotic properties which arise in this regime. In particular, we are interested in the possibility to engineer quantum phase transitions in these systems. One direction we explore is the study of two-photon coupling, a mechanism in which matter creates or absorb photons by pairs. This mechanism creates a rich phase diagram containing both phase transitions and instabilities. A second topic is the use of these transitions for sensing applications. Indeed, near the critical point, the system becomes extremely sensitive to external perturbations. We study a setup in which a single qubit is coupled to a bosonic field. We show that even this finite-size system displays a phase transition, which can be used to measure the frequency of the qubit and the field with improved accuracy. This protocol could be used to develop small-scale sensors. Finally, we study how the ability of a system to perform certain metrological tasks could be used to characterize and quantify nonclassicality, by using the formalism of resource theories. The first three chapters present the main concepts and key results in the fields of ultrastrong light-matter coupling, superradiant phase transitions, and quantum metrology. I have strived to write these chapters pedagogically; they can be used by non-specialists or students as an introduction to these domains. The three other chapters present my own research contributions. Although most of those have already been published elsewhere, this manuscript contains additional results, remarks, and perspectives, and should be considered as an improved version of the original papers., Comment: 209 pages, 31 figures. Codes used in this manuscript are available upon request. Comments welcome!

Published

2020

6. Dissipation-induced bistability in the two-photon Dicke model

Author

Garbe, Louis, Wade, Peregrine, Minganti, Fabrizio, Shammah, Nathan, Felicetti, Simone, and Nori, Franco

Subjects

Quantum Physics

Abstract

The Dicke model is a paradigmatic quantum-optical model describing the interaction of a collection of two-level systems with a single bosonic mode. Effective implementations of this model made it possible to observe the emergence of superradiance, i.e., cooperative phenomena arising from the collective nature of light-matter interactions. Via reservoir engineering and analogue quantum simulation techniques, current experimental platforms allow us not only to implement the Dicke model, but also to design more exotic interactions, such as the two-photon Dicke model. In the Hamiltonian case, this model presents an interesting phase diagram characterized by two quantum criticalities: a superradiant phase transition and a spectral collapse, that is, the coalescence of discrete energy levels into a continuous band. Here, we investigate the effects of both qubit and photon dissipation on the phase transition and on the instability induced by the spectral collapse. Using a mean-field decoupling approximation, we analytically obtain the steady-state expectation values of the observables signaling a symmetry breaking, identifying a first-order phase transition from the normal to the superradiant phase. Our stability analysis unveils a very rich phase diagram, which features stable, bistable, and unstable phases depending on dissipation rate.

Published

2019

7. Critical Quantum metrology with a finite-component quantum phase transition

Author

Garbe, Louis, Bina, Matteo, Keller, Arne, Paris, Matteo G. A., and Felicetti, Simone

Subjects

Quantum Physics, Condensed Matter - Mesoscale and Nanoscale Physics

Abstract

Physical systems close to a quantum phase transition exhibit a divergent susceptibility, suggesting that an arbitrarily-high precision may be achieved by exploiting quantum critical systems as probes to estimate a physical parameter. However, such an improvement in sensitivity is counterbalanced by the closing of the energy gap, which implies a critical slowing down and an inevitable growth of the protocol duration. Here, we design different metrological protocols that make use of the superradiant phase transition of the quantum Rabi model, a finite-component system composed of a single two-level atom interacting with a single bosonic mode. We show that, in spite of the critical slowing down, critical quantum optical systems can lead to a quantum-enhanced time-scaling of the quantum Fisher information, and so of the measurement sensitivity., Comment: 5 main text, 5 pages supplemental material

Published

2019

8. Metrological advantage at finite temperature for Gaussian phase estimation

Author

Garbe, Louis, Felicetti, Simone, Milman, Perola, Coudreau, Thomas, and Keller, Arne

Subjects

Quantum Physics

Abstract

In the context of phase estimation with Gaussian states, we introduce a quantifiable definition of metrological advantage that takes into account thermal noise in the preparation procedure. For a broad set of states, \textit{isotropic non-pure Gaussian states}, we show that squeezing is not only necessary, but sufficient, to achieve metrological advantage. We interpret our results in the framework of resource theory, and discuss possible sources of advantage other than squeezing. Our work is a step towards using phase estimation with pure and mixed state to define and quantify nonclassicality. This work is complementary with studies that defines nonclassicality using quadrature displacement estimation., Comment: Changes to wording, figures replaced

Published

2018

9. Dissipation-induced bistability in the two-photon Dicke model

Author

Garbe, Louis, Wade, Peregrine, Minganti, Fabrizio, Shammah, Nathan, Felicetti, Simone, and Nori, Franco

Published

2020

10. Non-Gaussian superradiant transition via three-body ultrastrong coupling

Author

Minganti, Fabrizio, primary, Garbe, Louis, additional, Le Boité, Alexandre, additional, and Felicetti, Simone, additional

Published

2023

11. The bosonic skin effect: boundary condensation in asymmetric transport

Author

Garbe, Louis Marie Francois, Minoguchi, Yuri Stefan, Huber, Julian, and Rabl, Peter

Subjects

ASEP, transport, Lasing, quantum optics

Abstract

We study the incoherent transport of bosonic particles through a one dimensional lattice with different left and right hopping rates, as modelled by the asymmetric simple inclusion process (ASIP). Specifically, we show that as the current passing through this system increases, a transition occurs, which is signified by the appearance of a characteristic zigzag pattern in the stationary density profile near the boundary. In this highly unusual transport phase, the local particle distribution alternates on every site between a thermal distribution and a Bose-condensed state with broken U(1)-symmetry. Furthermore, we show that the onset of this phase is closely related to the so-called non-Hermitian skin effect and coincides with an exceptional point in the spectrum of density fluctuations. Therefore, this effect establishes a direct connection between quantum transport, non-equilibrium condensation phenomena and non-Hermitian topology, which can be probed in cold-atom experiments or in systems with long-lived photonic, polaritonic and plasmonic excitations.

Published

2023

12. Exponential time-scaling of estimation precision by reaching a quantum critical point

Author

Garbe, Louis, primary, Abah, Obinna, additional, Felicetti, Simone, additional, and Puebla, Ricardo, additional

Published

2022

13. Exponential precision by reaching a quantum critical point

Author

Austrian Academy of Sciences, European Commission, Engineering and Physical Sciences Research Council (UK), Newcastle University, Garbe, Louis [0000-0002-1098-9006], Abah, Obinna [0000-0003-0193-4860], Puebla, Ricardo [0000-0002-1243-0839], Garbe, Louis, Abah, Obinna, Felicetti, Simone, Puebla, Ricardo, Austrian Academy of Sciences, European Commission, Engineering and Physical Sciences Research Council (UK), Newcastle University, Garbe, Louis [0000-0002-1098-9006], Abah, Obinna [0000-0003-0193-4860], Puebla, Ricardo [0000-0002-1243-0839], Garbe, Louis, Abah, Obinna, Felicetti, Simone, and Puebla, Ricardo

Abstract

Quantum metrology shows that by exploiting nonclassical resources it is possible to overcome the fundamental limit of precision found for classical parameter-estimation protocols. The scaling of the quantum Fisher information -- which provides an upper bound to the achievable precision -- with respect to the protocol duration is then of primarily importance to assess its performances. In classical protocols the quantum Fisher information scales linearly with time, while typical quantum-enhanced strategies achieve a quadratic (Heisenberg) or even higher-order polynomial scalings. Here we report a protocol that is capable of surpassing the polynomial scaling, and yields an exponential advantage. Such exponential advantage is achieved by approaching, but without crossing, the critical point of a quantum phase transition of a fully-connected model in the thermodynamic limit. The exponential advantage stems from the breakdown of the adiabatic condition close to a critical point. As we demonstrate, this exponential scaling is well captured by the new bound derived in arXiv:2110.04144, which in turn allows us to obtain approximate analytical expressions for the quantum Fisher information that agree with exact numerical simulations. In addition, we discuss the limitations to the exponential scaling when considering a finite-size system as well as its robustness against decoherence effects. Hence, our findings unveil a novel quantum metrological protocol whose precision scaling goes beyond the paradigmatic Heisenberg limit with respect to the protocol duration.

Published

2021

14. Critical quantum metrology with fully-connected models: from Heisenberg to Kibble-Zurek scaling

Author

Austrian Academy of Sciences, Austrian Science Fund, European Commission, Engineering and Physical Sciences Research Council (UK), Newcastle University, Garbe, Louis, Abah, Obinna, Felicetti, Simone, Puebla, Ricardo, Austrian Academy of Sciences, Austrian Science Fund, European Commission, Engineering and Physical Sciences Research Council (UK), Newcastle University, Garbe, Louis, Abah, Obinna, Felicetti, Simone, and Puebla, Ricardo

Abstract

Phase transitions represent a compelling tool for classical and quantum sensing applications. It has been demonstrated that quantum sensors can in principle saturate the Heisenberg scaling, the ultimate precision bound allowed by quantum mechanics, in the limit of large probe number and long measurement time. Due to the critical slowing down, the protocol duration time is of utmost relevance in critical quantum metrology. However, how the long-time limit is reached remains in general an open question. So far, only two dichotomic approaches have been considered, based on either static or dynamical properties of critical quantum systems. Here, we provide a comprehensive analysis of the scaling of the quantum Fisher information for different families of protocols that create a continuous connection between static and dynamical approaches. In particular, we consider fully-connected models, a broad class of quantum critical systems of high experimental relevance. Our analysis unveils the existence of universal precision-scaling regimes. These regimes remain valid even for finite-time protocols and finite-size systems. We also frame these results in a general theoretical perspective, by deriving a precision bound for arbitrary time-dependent quadratic Hamiltonians.

Published

2022

15. Critical quantum metrology with fully-connected models: from Heisenberg to Kibble–Zurek scaling

Author

Garbe, Louis, primary, Abah, Obinna, additional, Felicetti, Simone, additional, and Puebla, Ricardo, additional

Published

2022

16. Critical quantum metrology with fully-connected models: from Heisenberg to Kibbleâ€"Zurek scaling.

Author

Garbe, Louis, Abah, Obinna, Felicetti, Simone, and Puebla, Ricardo

Published

2022

17. Transitions de phase dans des systèmes lumière-matière pour la métrologie quantique

Author

Garbe, Louis, Laboratoire Matériaux et Phénomènes Quantiques (MPQ (UMR_7162)), Centre National de la Recherche Scientifique (CNRS)-Université de Paris (UP), Université de Paris, and Arne Keller

Subjects

Couplage Ultra-fort, [PHYS.PHYS]Physics [physics]/Physics [physics], Quantum Phase Transitions, Finite-size Systems, Métrologie Quantique, Quantum Sensing, Transitions de Phase Quantiques, Etats Gaussiens, Interaction Lumière-matière, Gaussian States, Ultrastrong Coupling Regime, Capteurs Quantiques, Systèmes de Taille Finie, Light-matter Interaction, Quantum Metrology

Abstract

When light and matter are weakly coupled, they can be described as two distinctive systems exchanging quanta of energy. By contrast, when their coupling strength becomes very large, the systems hybridize and form compounds that cannot be described in terms of light or matter only. In this Thesis, we will study some exotic properties which arise in this regime. In particular, we will be interested in the possibility to engineer quantum phase transitions in these systems. One direction we explore is the study of two-photon coupling, a mechanism in which photons are created or emitted in pairs. This mechanism creates a rich phase diagram containing both phase transitions and instabilities. Another point of interest is the possibility to use these transitions for sensing applications. Indeed, near the critical point, the system becomes extremely sensitive to external perturbations. We will present a protocol in which a single qubit coupled to a bosonic field. Despite its simplicity, this system displays a phase transition. Near the critical point, both the frequency of the qubit and the field can be measured with improved accuracy. Hence, finite-size transitions could be used to develop small-scale sensors. As last topic, we study how the ability of a system to perform certain metrological tasks could be used to characterize and quantify nonclassicality, by using the formalism of resource theories.; Lorsque lumière et matière sont faiblement couplées, elles peuvent être traitées comme des systèmes distincts, échangeant des quanta d’énergie. En revanche, lorsque le taux de couplage devient très élevé, les deux systèmes se mêlent pour former des excitations hybrides, qui ne peuvent être décrites isolément en termes de lumière ou de matière. Au long de cette dissertation, nous étudierons quelques-unes des propriétés exotiques qui surviennent dans ce régime. Nous accorderons notamment une grande attention à l’émergence de transitions de phase quantiques dans ces systèmes. L’un des axes de recherche développés ici est l’étude d’un mécanisme de couplage à deux photons, par lequel des photons sont créés ou absorbés par paires. Ce mécanisme crée un diagramme de phase très riche, présentant à la fois une transition de phase et des instabilités. Une autre étude porte sur l’utilisation de ces transitions de phase pour le développement de capteurs. En effet, à proximité du point critique, le système devient extrêmement sensible à des perturbations extérieures. Nous présenterons un protocole exploitant un unique système à deux niveaux, couplé à un champ bosonique. En dépit de sa simplicité, un tel système peut générer des transitions de phase. Près du point critique, la fréquence du champ et celle du système à deux niveaux peuvent toutes deux être mesurées avec une précision accrue. Ainsi, des transitions de phase dans des systèmes de taille finie pourraient être utilisées pour développer des capteurs de petite taille. Enfin, en utilisant le formalisme des théories de ressources, nous étudierons comment la capacité d’un système physique à effectuer des tâches métrologiques pourrait être utilisée pour caractériser et quantifier la «non-classicalité» d’un tel système.

Published

2020

18. Critical Quantum Metrology with a Finite-Component Quantum Phase Transition

Author

Garbe, Louis, primary, Bina, Matteo, additional, Keller, Arne, additional, Paris, Matteo G. A., additional, and Felicetti, Simone, additional

Published

2020

19. Metrological advantage at finite temperature for Gaussian phase estimation

Author

Garbe, Louis, primary, Felicetti, Simone, additional, Milman, Perola, additional, Coudreau, Thomas, additional, and Keller, Arne, additional

Published

2019