Your search keyword '"Sassetti, Maura"' showing total 369 results

1. Cyclic solid-state quantum battery: Thermodynamic characterization and quantum hardware simulation

Author

Razzoli, Luca, Gemme, Giulia, Khomchenko, Ilia, Sassetti, Maura, Ouerdane, Henni, Ferraro, Dario, and Benenti, Giuliano

Subjects

Quantum Physics, Condensed Matter - Mesoscale and Nanoscale Physics

Abstract

We introduce a cyclic quantum battery model, based on an interacting bipartite system, weakly coupled to a thermal bath. The working cycle of the battery consists of four strokes: system thermalization, disconnection of subsystems, ergotropy extraction, and reconnection. The thermal bath acts as a charger in the thermalization stroke, while ergotropy extraction is possible because the ensuing thermal state is no longer passive after the disconnection stroke. Focusing on the case of two interacting qubits, we show that phase coherence, in the presence of non-trivial correlations between the qubits, can be exploited to reach working regimes with efficiency higher than 50% while providing finite ergotropy. Our protocol is illustrated through a simple and feasible circuit model of a cyclic superconducting quantum battery. Furthermore, we simulate the considered cycle on superconducting IBM quantum machines. The good agreement between the theoretical and simulated results strongly suggests that our scheme for cyclic quantum batteries can be successfully realized in superconducting quantum hardware., Comment: 20 pages, 9 figures

Published

2024

2. Emerging Majorana bound states in superconducting Haldane nanoribbons

Author

Traverso, Simone, Ziani, Niccolò Traverso, Sassetti, Maura, and Dominguez, Fernando

Subjects

Condensed Matter - Mesoscale and Nanoscale Physics, Condensed Matter - Superconductivity

Abstract

We investigate the topological phase diagram of the $p$-wave superconducting Haldane model. In two dimensions, we find a topological nodal superconducting phase, which exhibits a chiral Majorana mode propagating along the edges of nanoribbons with cylindrical boundary conditions. This phase is however unstable in a finite two-dimensional rectangular-shaped lattice, yielding corner states close to zero energy in a flake with alternating zigzag and armchair edges. When we reduce one of the dimensions, quantum confinement gaps out the bulk bands faster than the edge states. In this scenario, hybridization between the edge states can then result in Majorana zero modes. Our results hence suggest quantum confinement as a crucial ingredient in building quasi-one-dimensional topological superconducting phases out of two-dimensional nodal topological superconductors. Furthermore, we characterize the emergence of this novel topological phase by means of its topological invariant, coinciding with a quantized conductance of $2 e^2/h$ in a normal-superconducting junction., Comment: 23 pages, 8 figures

Published

2024

3. Synchronization-induced violation of thermodynamic uncertainty relations

Author

Razzoli, Luca, Carrega, Matteo, Cavaliere, Fabio, Benenti, Giuliano, and Sassetti, Maura

Subjects

Quantum Physics, Condensed Matter - Mesoscale and Nanoscale Physics

Abstract

Fluctuations affect the functionality of nanodevices. Thermodynamic uncertainty relations (TURs), derived within the framework of stochastic thermodynamics, show that a minimal amount of dissipation is required to obtain a given relative energy current dispersion, that is, current precision has a thermodynamic cost. It is therefore of great interest to explore the possibility that TURs are violated, particularly for quantum systems, leading to accurate currents at lower cost. Here, we show that two quantum harmonic oscillators are synchronized by coupling to a common thermal environment, at strong dissipation and low temperature. In this regime, periodically modulated couplings to a second thermal reservoir, breaking time-reversal symmetry and taking advantage of non-Markovianity of this latter reservoir, lead to strong violation of TURs for local work currents, while maintaining finite output power. Our results pave the way for the use of synchronization in the thermodynamics of precision., Comment: 15 pages, 10 figures. This is the Accepted Manuscript version of an article accepted for publication in "Quantum Science and Technology". IOP Publishing Ltd is not responsible for any errors or omissions in this version of the manuscript or any version derived from it. The Version of Record is available online at https://www.doi.org/10.1088/2058-9565/ad6fc9

Published

2024

4. Anomalous supercurrent and diode effect in locally perturbed topological Josephson junctions

Author

Fracassi, Samuele, Traverso, Simone, Ziani, Niccolò Traverso, Carrega, Matteo, Heun, Stefan, and Sassetti, Maura

Subjects

Condensed Matter - Superconductivity

Abstract

The simultaneous breaking of time-reversal and inversion symmetry can lead to peculiar effects in Josephson junctions, such as the anomalous Josephson effect or supercurrent rectification, which is a dissipationless analog of the diode effect. Due to their impact in new quantum technologies, it is important to find robust platforms and external means to manipulate the above effects in a controlled way. Here, we theoretically consider a Josephson junction based on a quantum spin Hall system as the normal channel, subjected to a magnetic field in the direction defined by spin-momentum locking, and in presence of a local tip in close proximity to one of the metallic edges in the normal region. We consider different local perturbations, model normal and magnetic tips, and study how they affect the Josephson response of the device. In particular, we argue that magnetic tips are a useful tool that allows for tunability of both $\phi_0$ response and supercurrent rectification., Comment: Article: 7 pages, 4 figures. Supplementary Materials: 3 pages, 0 figures

Published

2024

5. Controlling energy storage crossing quantum phase transitions in an integrable spin quantum battery

Author

Grazi, Riccardo, Shaikh, Daniel Sacco, Sassetti, Maura, Ziani, Niccolò Traverso, and Ferraro, Dario

Subjects

Quantum Physics, Condensed Matter - Mesoscale and Nanoscale Physics

Abstract

We investigate the performance of a one-dimensional dimerized XY chain as a spin quantum battery. Such integrable model shows a rich quantum phase diagram that emerges through a mapping of the spins onto auxiliary fermionic degrees of freedom. We consider a charging protocol relying on the double quench of an internal parameter, namely the strength of the dimerization, and address the energy stored in the systems. We observe three distinct regimes, depending on the time-scale characterizing the duration of the charging: a short-time regime related to the dynamics of the single dimers, a long-time regime related to the recurrence time of the system at finite size, and a thermodynamic limit time regime. In the latter, the energy stored is almost unaffected by the charging time and the precise values of the charging parameters, provided the quench crosses a quantum phase transition. Such a robust many-body effect, that characterizes also other models like the quantum Ising chain in a transverse field, as we prove analytically, can play a relevant role in the design of stable solid-state quantum batteries., Comment: 6 pages (+ 8 SM), 4 figures (+ 5 SM)

Published

2024

6. Boosting energy transfer between quantum devices through spectrum engineering in the dissipative ultrastrong coupling regime

Author

Crescente, Alba, Ferraro, Dario, and Sassetti, Maura

Subjects

Quantum Physics, Condensed Matter - Mesoscale and Nanoscale Physics

Abstract

The coherent energy transfer between two quantum devices (a quantum charger and a quantum battery) mediated by a photonic cavity is investigated, in presence of dissipative environments, with particular focus on the the ultrastrong coupling regime. Here, very short transfer times and high charging power can be achieved in comparison with the usually addressed weak coupling case. Such phenomenology is further magnified by the presence of level crossings appearing in the energy spectrum and which reveal very robust against dissipative environmental effects. Moreover, by carefully control the physical parameters of the model, e.g. the matter-radiation coupling and the frequencies of the system, it is possible to tune these crossings making this device more flexible and experimentally feasible. Finally to broaden our analysis, we assume the possibility of choosing between a Fock and a coherent initial state of the cavity, with the latter showing better energetic performances., Comment: 13 pages, 11 figures

Published

2023

7. Towards a phase diagram of the topologically frustrated XY chain

Author

Shaikh, Daniel Sacco, Catalano, Alberto Giuseppe, Cavaliere, Fabio, Franchini, Fabio, Sassetti, Maura, and Ziani, Niccolò Traverso

Subjects

Condensed Matter - Statistical Mechanics, Condensed Matter - Strongly Correlated Electrons, Quantum Physics

Abstract

Landau theory's implicit assumption that microscopic details cannot affect the system's phases has been challenged only recently in systems such as antiferromagnetic quantum spin chains with periodic boundary conditions, where topological frustration can be induced. In this work, we show that the latter modifies the zero temperature phase diagram of the XY chain in a transverse magnetic field by inducing new quantum phase transitions. In doing so, we come across the first case of second order boundary quantum phase transition characterized by a quartic dispersion relation. Our analytical results are supported by numerical investigations and lay the foundation for understanding the phase diagram of this frustrated model.

Published

2023

8. Efficiency and thermodynamic uncertainty relations of a dynamical quantum heat engine

Author

Razzoli, Luca, Cavaliere, Fabio, Carrega, Matteo, Sassetti, Maura, and Benenti, Giuliano

Published

2024

9. Dissipation-induced collective advantage of a quantum thermal machine

Author

Carrega, Matteo, Razzoli, Luca, Erdman, Paolo Andrea, Cavaliere, Fabio, Benenti, Giuliano, and Sassetti, Maura

Subjects

Quantum Physics, Condensed Matter - Mesoscale and Nanoscale Physics

Abstract

Do quantum correlations lead to better performance with respect to several different systems working independently? For quantum thermal machines, the question is whether a working medium (WM) made of $N$ constituents exhibits better performance than $N$ independent engines working in parallel. Here, by inspecting a microscopic model with the WM composed by two non-interacting quantum harmonic oscillators, we show that the presence of a common environment can mediate non-trivial correlations in the WM leading to better quantum heat engine performance -- maximum power and efficiency -- with respect to an independent configuration. Furthermore, this advantage is striking for strong dissipation, a regime in which two independent engines cannot deliver any useful power. Our results show that dissipation can be exploited as a useful resource for quantum thermal engines, and are corroborated by optimization techniques here extended to non-Markovian quantum heat engines., Comment: Accepted Manuscript: Main text (13 pages, 8 figures) + Supplementary Material (9 pages, 3 figures). This article may be downloaded for personal use only. Any other use requires prior permission of the author and AIP Publishing. This article appeared in AVS Quantum Science 6, 025001 (2024) and may be found at https://doi.org/10.1116/5.0190340

Published

2023

10. Phase diagram of the topologically frustrated XY chain

Author

Sacco Shaikh, Daniel, Catalano, Alberto Giuseppe, Cavaliere, Fabio, Franchini, Fabio, Sassetti, Maura, and Traverso Ziani, Niccolò

Published

2024

11. Emerging topological bound states in Haldane model zigzag nanoribbons

Author

Traverso, Simone, Sassetti, Maura, and Ziani, Niccolò Traverso

Subjects

Condensed Matter - Mesoscale and Nanoscale Physics

Abstract

Zigzag nanoribbons hosting the Haldane Chern insulator model are considered. In this context, a reentrant topological phase, characterized by the emergence of quasi zero dimensional in-gap states, is discussed. The bound states, which reside in the gap opened by the hybridization of the counter-propagating edge modes of the Haldane phase, are localized at the ends of the strip and are found to be robust against on-site disorder. These findings are supported by the behavior of the Zak phase over the parameter space, which exhibits jumps of $\pi$ in correspondence to the phase transitions between the trivial and the non-trivial phases. The effective mass inversion leading to the jumps in the Zak phase is interpreted in a low energy framework. Setups with non-uniform parameters also show topological bound states via the Jackiw-Rebbi mechanism. All the properties reported are shown to be extremely sensitive to the strip width., Comment: Article: 22 pages, 6 figures. Supplementary Information: 21 pages, 9 figures

Published

2023

12. Analytically Solvable Model for Qubit-Mediated Energy Transfer between Quantum Batteries

Author

Crescente, Alba, Ferraro, Dario, Carrega, Matteo, and Sassetti, Maura

Subjects

Quantum Physics, Condensed Matter - Mesoscale and Nanoscale Physics

Abstract

The coherent energy transfer between two identical two-level systems is investigated. Here, the first quantum system plays the role of a charger, while the second can be seen as a quantum battery. Firstly, a direct energy transfer between the two objects is considered and then compared to a transfer mediated by an additional intermediate two-level system. In this latter case, it is possible to distinguish between a two-step process, where the energy is firstly transferred from the charger to the mediator and only after from the mediator to the battery, and a single-step in which the two transfers occurs simultaneously. The differences between these configurations are discussed in the framework of an analytically solvable model completing what recently discussed in literature., Comment: 27 pages, 9 figures

Published

2023

13. Reconstruction-Induced $\varphi_0$ Josephson Effect in Quantum Spin Hall Constrictions

Author

Vigliotti, Lucia, Cavaliere, Fabio, Passetti, Giacomo, Sassetti, Maura, and Ziani, Niccolò Traverso

Subjects

Condensed Matter - Superconductivity, Condensed Matter - Mesoscale and Nanoscale Physics

Abstract

The simultaneous breaking of time-reversal and inversion symmetry, in connection to superconductivity, leads to transport properties with disrupting scientific and technological potential. Indeed, the anomalous Josephson effect and the superconducting-diode effect hold promises to enlarge the technological applications of superconductors and nanostructures in general. In this context, the system we theoretically analyze is a Josephson junction (JJ) with coupled reconstructed topological channels as a link; such channels are at the edges of a two-dimensional topological insulator (2DTI). We find a robust $\varphi_0$ Josephson effect without requiring the presence of external magnetic fields. Our results, which rely on a fully analytical analysis, are substantiated by means of symmetry arguments: Our system breaks both time-reversal symmetry and inversion symmetry. Moreover, the anomalous current increases as a function of temperature. We interpret this surprising temperature dependence by means of simple qualitative arguments based on Fermi's golden rule., Comment: 13 pages, 3 figures

Published

2023

14. Emerging topological bound states in Haldane model zigzag nanoribbons

Author

Traverso, Simone, Sassetti, Maura, and Traverso Ziani, Niccolò

Published

2024

15. An exact local mapping from clock-spins to fermions

Author

Traverso, Simone, Fleckenstein, Christoph, Sassetti, Maura, and Ziani, Niccolò Traverso

Subjects

Condensed Matter - Statistical Mechanics

Abstract

Clock-spin models are attracting great interest, due to both their rich phase diagram and their connection to parafermions. In this context, we derive an exact local mapping from clock-spin to fermionic partition functions. Such mapping, akin to techniques introduced by Fedotov and Popov for spin $\frac{1}{2}$ chains, grants access to well established numerical tools for the perturbative treatment of fermionic systems in the clock-spin framework. Moreover, in one dimension, it allows to use bosonization to access the low energy properties of clock-spin models. Finally, aside from the direct application in clock-spin models, this new mapping enables the conception of interesting fermionic models, based on the clock-spin counterparts., Comment: 26 pages, 0 figures, Submission to SciPost

Published

2023

16. Efficiency and thermodynamic uncertainty relations of a dynamical quantum heat engine

Author

Razzoli, Luca, Cavaliere, Fabio, Carrega, Matteo, Sassetti, Maura, and Benenti, Giuliano

Subjects

Quantum Physics

Abstract

In the quest for high-performance quantum thermal machines, looking for an optimal thermodynamic efficiency is only part of the issue. Indeed, at the level of quantum devices, fluctuations become extremely relevant and need to be taken into account. In this paper we study the thermodynamic uncertainty relations for a quantum thermal machine with a quantum harmonic oscillator as a working medium, connected to two thermal baths, one of which is dynamically coupled. We show that parameters can be found such that the machine operates both as a quantum engine or refrigerator, with both sizeable efficiency and small fluctuations., Comment: 16 pages, 5 color figures. This version of the article has been accepted for publication, after peer review but is not the Version of Record and does not reflect post-acceptance improvements, or any corrections. The Version of Record is available online at: https://doi.org/10.1140/epjs/s11734-023-00949-8

Published

2023

17. Off-resonant Dicke Quantum Battery: Charging by Virtual Photons

Author

Gemme, Giulia, Andolina, Gian Marcello, Pellegrino, Francesco Maria Dimitri, Sassetti, Maura, and Ferraro, Dario

Subjects

Quantum Physics, Condensed Matter - Mesoscale and Nanoscale Physics

Abstract

We investigate a Dicke quantum battery in the dispersive regime, where the photons trapped into a resonant cavity are way more energetic with respect to the two-level systems embedded into it. Under such off-resonant conditions, even an empty cavity can lead to the charging of the quantum battery through a proper modulation of the matter-radiation coupling. This counterintuitive behaviour has its roots in the effective interaction between two-level systems mediated by virtual photons emerging from the fluctuations of the quantum electromagnetic field. In order to properly characterize it, we address relevant figures of merit such as the stored energy, the time required to reach the maximum charging, and the averaged charging power. Moreover, the possibility of efficiently extracting energy in various ranges of parameters is discussed. The scaling of stored energy and power as a function of the number $N$ of two-level systems and for different values of the matter-radiation coupling is also discussed showing, in the strong coupling regime, performances in line with what reported for the Dicke quantum battery in the resonant regime., Comment: 18 pages, 5 figures

Published

2023

18. Effects of the Vertices on the Topological Bound States in a Quasicrystalline Topological Insulator

Author

Traverso, Simone, Ziani, Niccolò Traverso, and Sassetti, Maura

Subjects

Condensed Matter - Mesoscale and Nanoscale Physics

Abstract

The experimental realization of twisted bilayer graphene strongly pushed the inspection of bilayer systems. In this context, it was recently shown that a two layer Haldane model with a thirty degree rotation angle between the layers represents a higher order topological insulator, with zero-dimensional states isolated in energy and localized at the physical vertices of the nanostructure. We show, within a numerical tight binding approach, that the energy of the zero dimensional states strongly depends on the geometrical structure of the vertices. In the most extreme cases, once a specific band gap is considered, these bound states can even disappear just by changing the vertex structure., Comment: 12 pages, 6 figures, published on Symmetry

Published

2023

19. Effects of the Spatial Extension of the Edge Channels on the Interference Pattern of a Helical Josephson Junction

Author

Vigliotti, Lucia, Calzona, Alessio, Ziani, Niccolò Traverso, Bergeret, F. Sebastian, Sassetti, Maura, and Trauzettel, Björn

Subjects

Condensed Matter - Superconductivity, Condensed Matter - Mesoscale and Nanoscale Physics

Abstract

Josephson junctions (JJs) in the presence of a magnetic field exhibit qualitatively different interference patterns depending on the spatial distribution of the supercurrent through the junction. In JJs based on two-dimensional topological insulators (2DTIs), the electrons/holes forming a Cooper pair (CP) can either propagate along the same edge or be split into the two edges. The former leads to a SQUID-like interference pattern, with the superconducting flux quantum $\phi_0$ (where $\phi_0=h/2e$) as a fundamental period. If CPs' splitting is additionally included, the resultant periodicity doubles. Since the edge states are typically considered to be strongly localized, the critical current does not decay as a function of the magnetic field. The present paper goes beyond this approach and inspects a topological JJ in the tunneling regime featuring extended edge states. It is here considered the possibility that the two electrons of a CP propagate and explore the junction independently over length scales comparable to the superconducting coherence length. As a consequence of the spatial extension, a decaying pattern with different possible periods is obtained. In particular, it is shown that, if crossed Andreev reflections (CARs) are dominant and the edge states overlap, the resulting interference pattern features oscillations whose periodicity approaches $2\phi_0$., Comment: 13 pages, 5 figures

Published

2023

20. Hybrid quantum thermal machines with dynamical couplings

Author

Cavaliere, Fabio, Razzoli, Luca, Carrega, Matteo, Benenti, Giuliano, and Sassetti, Maura

Subjects

Quantum Physics, Condensed Matter - Mesoscale and Nanoscale Physics

Abstract

Quantum thermal machines can perform useful tasks, such as delivering power, cooling, or heating. In this work, we consider hybrid thermal machines, that can execute more than one task simultaneously. We characterize and find optimal working conditions for a three-terminal quantum thermal machine, where the working medium is a quantum harmonic oscillator, coupled to three heat baths, with two of the couplings driven periodically in time. We show that it is possible to operate the thermal machine efficiently, in both pure and hybrid modes, and to switch between different operational modes simply by changing the driving frequency. Moreover, the proposed setup can also be used as a high-performance transistor, in terms of output--to--input signal and differential gain. Due to its versatility and tunability, our model may be of interest for engineering thermodynamic tasks and for thermal management in quantum technologies., Comment: Original submitted version of the manuscript: 14 pages, 5(+1) color figures

Published

2023

21. Role of the edges in a quasicrystalline Haldane model

Author

Traverso, Simone, Sassetti, Maura, and Ziani, Niccolò Traverso

Subjects

Condensed Matter - Mesoscale and Nanoscale Physics

Abstract

We study the role of the edges in determining the features of the topological phase in a quasicrystalline higher order topological insulator. We consider a specific model consisting of two stacked Haldane models with opposite Chern number and a $30^\circ$ twist, whose structure is crystallographically equivalent to that of the graphene quasicrystal. We find that the gap-opening in the low energy spectrum of the higher order topological insulator occurs at different energies when different kinds of edges are considered. Crucially, bearded bonds appear to be necessary for the gap to appear close to the charge neutrality point. In the more realistic case of zigzag edges, the gap opens symmetrically in the electron and hole sectors, away from zero energy. We explain our findings by inspecting the edge-bands of the decoupled bilayer, in the approximation of quasi-periodicity., Comment: 10 pages, 9 figures

Published

2022

22. Dynamical heat engines with non--Markovian reservoirs

Author

Cavaliere, Fabio, Carrega, Matteo, De Filippis, Giulio, Cataudella, Vittorio, Benenti, Giuliano, and Sassetti, Maura

Subjects

Quantum Physics, Condensed Matter - Mesoscale and Nanoscale Physics

Abstract

We discuss whether, and under which conditions, it is possible to realize a heat engine simply by dynamically modulating the couplings between the quantum working medium and thermal reservoirs. For that purpose, we consider the paradigmatic model of a quantum harmonic oscillator, exposed to a minimal modulation, that is, a monochromatic driving of the coupling to only one of the thermal baths. We demonstrate, at any order in the system/bath coupling strength, that in this setup non--Markovianity of the bath is a necessary condition to obtain a heat engine. In addition, we identify suitable structured environments for the engine to approach the ideal Carnot efficiency. Our results open up new possibilities for the use of non--Markovian open quantum systems for the construction and optimization of quantum thermal machines., Comment: Final revision as published on Physical Review Research: 19 pages, 7 color figures

Published

2022

23. IBM quantum platforms: a quantum battery perspective

Author

Gemme, Giulia, Grossi, Michele, Ferraro, Dario, Vallecorsa, Sofia, and Sassetti, Maura

Subjects

Quantum Physics, Condensed Matter - Mesoscale and Nanoscale Physics

Abstract

We characterize for the first time the performances of IBM quantum chips as quantum batteries, specifically addressing the single-qubit Armonk processor. By exploiting the Pulse access enabled to some of the IBM Quantum processors via the Qiskit package, we investigate advantages and limitations of different profiles for classical drives used to charge these miniaturized batteries, establishing the optimal compromise between charging time and stored energy. Moreover, we consider the role played by various possible initial conditions on the functioning of the quantum batteries. As main result of our analysis, we observe that unavoidable errors occurring in the initialization phase of the qubit, which can be detrimental for quantum computing applications, only marginally affects energy transfer and storage. This can lead counter-intuitively to improvements of the performances. This is a strong indication of the fact that IBM quantum devices are already in the proper range of parameters to be considered as good and stable quantum batteries, comparable to state of the art devices recently discussed in literature., Comment: 13 pages, 4 figures

Published

2022

24. Enhancing coherent energy transfer between quantum devices via a mediator

Author

Crescente, Alba, Ferraro, Dario, Carrega, Matteo, and Sassetti, Maura

Subjects

Condensed Matter - Mesoscale and Nanoscale Physics, Quantum Physics

Abstract

We investigate the coherent energy transfer between two quantum systems mediated by a quantum bus. In particular, we consider the energy transfer process between two qubits, and how it can be influenced by using a third qubit or photons in a resonant cavity as mediators. Inspecting different figures of merit and considering both on and off-resonance configurations, we characterize the energy transfer performances. We show that, while the qubit-mediated transfer shows no advantages with respect to a direct coupling case, the cavity-mediated one is progressively more and more efficient as function of the number of photons stored in the cavity that acts as a quantum bus. The speeding-up of the energy transfer time, due to a quantum mediator paves the way for new architecture designs in quantum technologies and energy based quantum logics., Comment: 19 pages, 11 figures

Published

2022

25. Anomalous flux periodicity in proximitised quantum spin Hall constrictions

Author

Vigliotti, Lucia, Calzona, Alessio, Trauzettel, Björn, Sassetti, Maura, and Ziani, Niccolò Traverso

Subjects

Condensed Matter - Mesoscale and Nanoscale Physics, Condensed Matter - Superconductivity

Abstract

We theoretically analyse a long constriction between the helical edge states of a two-dimensional topological insulator. The constriction is laterally tunnel-coupled to two superconductors and a magnetic field is applied perpendicularly to the plane of the two-dimensional topological insulator. The Josephson current is calculated analytically up to second order in the tunnel coupling both in the absence and in the presence of a bias (DC and AC Josephson currents). We show that in both cases the current acquires an anomalous $4\pi$-periodicity with respect to the magnetic flux that is absent if the two edges are not tunnel-coupled to each other. The result, that provides at the same time a characterisation of the device and a possible experimental signature of the coupling between the edges, is stable against temperature. The processes responsible for the anomalous $4\pi$-periodicity are the ones where, within the constriction, one of the two electrons forming a Cooper pair tunnels between the two edges., Comment: 29 pages, 9 figures

Published

2022

26. Engineering dynamical couplings for quantum thermodynamic tasks

Author

Carrega, Matteo, Cangemi, Loris Maria, De Filippis, Giulio, Cataudella, Vittorio, Benenti, Giuliano, and Sassetti, Maura

Subjects

Condensed Matter - Mesoscale and Nanoscale Physics, Quantum Physics

Abstract

Describing the thermodynamic properties of quantum systems far from equilibrium is challenging, in particular when the system is strongly coupled to its environment, or when memory effects cannot be neglected. Here, we address such regimes when the system-baths couplings are periodically modulated in time. We show that the couplings modulation, usually associated to a purely dissipative effect when done nonadiabatically, can be suitably engineered to perform thermodynamic tasks. In particular, asymmetric couplings to two heat baths can be used to extract heat from the cold reservoir and to realize an ideal heat rectifier, where the heat current can be blocked either in the forward or in the reverse configuration by simply tuning the frequency of the couplings modulation. Interestingly, both effects take place in the low-temperature, quantum non Markovian regime. Our work paves the way for the use of optimal control techniques for heat engines and refrigerators working in regimes beyond standard approaches., Comment: 19 pages, 7 figures

Published

2021

27. Rashba-controlled thermal valve in helical liquids

Author

Calzona, Alessio, Ziani, Niccolò Traverso, Carrega, Matteo, and Sassetti, Maura

Subjects

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

Abstract

In the context of one-dimensional fermionic systems, helical Luttiger liquids are not only characterized by intriguing spin properties, but also by the possibility to be manipulated by means of electrostatic gates, exploiting finite Rashba coupling. We use this property to show that a heterostructure composed of a helical Luttinger liquid, contacted to two metallic leads and supplemented by top gates, can be used as a tunable thermal valve. By relying on bosonization techniques and scattering of plasmonic modes, we investigate the performance of this valve with respect to electron-electron interactions, temperature, and properties of the gates. The maximal modulation of the thermal conductance that the proposed device can achieve is, for experimentally relevant parameters, around $7 \%$. Such variation can be both positive or negative. Moreover, a modification in the geometry of the gate can lead to particular temperature dependencies related to interference effects. We also argue that the effects we predict can be used to establish the helical nature of the edge states in two-dimensional topological insulators., Comment: 12 pages, 7 figures

Published

2021

28. Characterization of a Two-Photon Quantum Battery: Initial Conditions, Stability and Work Extraction

Author

Delmonte, Anna, Crescente, Alba, Carrega, Matteo, Ferraro, Dario, and Sassetti, Maura

Subjects

Condensed Matter - Mesoscale and Nanoscale Physics, Quantum Physics

Abstract

We consider a quantum battery that is based on a two-level system coupled with a cavity radiation by means of a two-photon interaction. Various figures of merit, such as stored energy, average charging power, energy fluctuations, and extractable work are investigated, considering, as possible initial conditions for the cavity, a Fock state, a coherent state, and a squeezed state. We show that the first state leads to better performances for the battery. However, a coherent state with the same average number of photons, even if it is affected by stronger fluctuations in the stored energy, results in quite interesting performance, in particular since it allows for almost completely extracting the stored energy as usable work at short enough times., Comment: 15 pages, 7 figures

Published

2021

29. Optimal energy conversion through anti-adiabatic driving breaking time-reversal symmetry

Author

Cangemi, Loris Maria, Carrega, Matteo, De Candia, Antonio, Cataudella, Vittorio, De Filippis, Giulio, Sassetti, Maura, and Benenti, Giuliano

Subjects

Condensed Matter - Mesoscale and Nanoscale Physics, Quantum Physics

Abstract

Starting with Carnot engine, the ideal efficiency of a heat engine has been associated with quasi-static transformations and vanishingly small output power. Here, we exactly calculate the thermodynamic properties of a isothermal heat engine, in which the working medium is a periodically driven underdamped harmonic oscillator, focusing instead on the opposite, anti-adiabatic limit, where the period of a cycle is the fastest time scale in the problem. We show that in that limit it is possible to approach the ideal energy conversion efficiency $\eta=1$, with finite output power and vanishingly small relative power fluctuations. The simultaneous realization of all the three desiderata of a heat engine is possible thanks to the breaking of time-reversal symmetry. We also show that non-Markovian dynamics can further improve the power-efficiency trade-off.

Published

2020

30. Ultrafast charging in a two-photon Dicke quantum battery

Author

Crescente, Alba, Carrega, Matteo, Sassetti, Maura, and Ferraro, Dario

Subjects

Condensed Matter - Mesoscale and Nanoscale Physics, Quantum Physics

Abstract

We consider a collection of two level systems, such as qubits, embedded into a microwave cavity as a promising candidate for the realization of high power quantum batteries. In this perspective, the possibility to design devices where the conventional single-photon coupling is suppressed and the dominant interaction is mediated by two-photon processes is investigated, opening the way to an even further enhancement of the charging performance. By solving a Dicke model with both single- and two-photon coupling we determine the range of parameters where the latter unconventional interaction dominates the dynamics of the system leading to better performances both in the charging times and average charging power of the QB compared to the single-photon case. In addition, the scaling of the maximum stored energy, fluctuations and charging power with the finite number of qubits N is inspected. While the energy and fluctuations scale linearly with N, the quadratic growth of the average power leads to a relevant improvement of the charging performance of quantum batteries based on this scheme with respect to the purely single-photon coupling case. Moreover, it is shown that the charging process is progressively faster by increasing the coupling from the weak to the ultra-strong regime., Comment: 13 pages, 9 figures

Published

2020

31. Signature of Generalized Gibbs Ensemble Deviation from Equilibrium: Negative Absorption Induced by a Local Quench

Author

Rossi, Lorenzo, Dolcini, Fabrizio, Cavaliere, Fabio, Ziani, Niccolò Traverso, Sassetti, Maura, and Rossi, Fausto

Subjects

Condensed Matter - Mesoscale and Nanoscale Physics, Condensed Matter - Statistical Mechanics

Abstract

When a parameter quench is performed in an isolated quantum system with a complete set of constants of motion, its out of equilibrium dynamics is considered to be well captured by the Generalized Gibbs Ensemble (GGE), characterized by a set $\{\lambda_\alpha\}$ of coefficients related to the constants of motion. We determine the most elementary GGE deviation from the equilibrium distribution that leads to detectable effects. By quenching a suitable local attractive potential in a one-dimensional electron system, the resulting GGE differs from equilibrium by only one single $\lambda_{\alpha}$, corresponding to the emergence of an only partially occupied bound state lying below a fully occupied continuum of states. The effect is shown to induce optical gain, i.e., a negative peak in the absorption spectrum, indicating the stimulated emission of radiation, enabling one to identify GGE signatures in fermionic systems through optical measurements. We discuss the implementation in realistic setups., Comment: 11 pages, 4 figures

Published

2020

32. Dissipative dynamics of an open quantum battery

Author

Carrega, Matteo, Crescente, Alba, Ferraro, Dario, and Sassetti, Maura

Subjects

Condensed Matter - Mesoscale and Nanoscale Physics, Quantum Physics

Abstract

Coupling with an external environment inevitably affects the dynamics of a quantum system. Here, we consider how charging performances of a quantum battery, modelled as a two level system, are influenced by the presence of an Ohmic thermal reservoir. The latter is coupled to both longitudinal and transverse spin components of the quantum battery including decoherence and pure dephasing mechanisms. Charging and discharging dynamics of the quantum battery, subjected to a static driving, are obtained exploiting a proper mapping into the so-called spin-boson model. Analytic expressions for the time evolution of the energy stored in the weak coupling regime are presented relying on a systematic weak damping expansion. Here, decoherence and pure dephasing dissipative coupling are discussed in details. We argue that the former results in better charging performances, showing also interesting features reminiscent of the Lamb shift level splitting renormalization induced by the presence of the reservoir. Charging stability is also addressed, by monitoring the energy behaviour after the charging protocol has been switched off. This study presents a general framework to investigate relaxation effects, able to include also non Markovian effects, and it reveals the importance of controlling and, possibly, engineering system-bath coupling in the realization of quantum batteries., Comment: 29 pages (single column), 6 figures

Published

2020

33. Violation of TUR in a periodically driven work-to-work converter from weak to strong dissipation

Author

Cangemi, Loris Maria, Cataudella, Vittorio, Benenti, Giuliano, Sassetti, Maura, and De Filippis, Giulio

Subjects

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

Abstract

We study a model of isothermal steady-state work-to-work converter, where a single quantum two-level system (TLS) driven by time-dependent periodic external fields acts as the working medium and is permanently put in contact with a thermal reservoir at fixed temperature $T$. By combining Short-Iterative Lanczos (SIL) method and analytic approaches, we study the converter performance in the linear response regime and in a wide range of driving frequencies, from weak to strong dissipation. We show that for our ideal quantum machine several parameter ranges exist where a violation of Thermodynamics Uncertainty Relations (TUR) occurs. We find the violation to depend on the driving frequency and on the dissipation strength, and we trace it back to the degree of coherence of the quantum converter. We eventually discuss the influence of other possible sources of violation, such as non-Markovian effects during the converter dynamics.

Published

2020

34. Levitons in helical liquids with Rashba spin-orbit coupling probed by a superconducting contact

Author

Ronetti, Flavio, Carrega, Matteo, and Sassetti, Maura

Subjects

Condensed Matter - Mesoscale and Nanoscale Physics

Abstract

We consider transport properties of a single edge of a two-dimensional topological insulators, in presence of Rashba spin-orbit coupling, driven by two external time-dependent voltages and connected to a thin superconductor. We focus on the case of a train of Lorentzian-shaped pulses, which are known to generate coherent single-electron excitations in two-dimensional electron gas, and prove that they are minimal excitations for charge transport also in helical edge states, even in the presence of spin-orbit interaction. Importantly, these properties of Lorentzian-shaped pulses can be tested computing charge noise generated by the scattering of particles at the thin superconductor. This represents a novel setup where electron quantum optics experiments with helical states can be implemented, with the superconducting contact as an effective beamsplitter. By elaborating on this configuration, we also evaluate charge noise in a collisional Hong-Ou-Mandel configuration, showing that, due to the peculiar effects induced by Rashba interaction, a non-vanishing dip at zero delay appears., Comment: 16 pages, 5 figures

Published

2019

35. Spectral properties of interacting helical channels driven by Lorentzian pulses

Author

Acciai, Matteo, Calzona, Alessio, Carrega, Matteo, Martin, Thierry, and Sassetti, Maura

Subjects

Condensed Matter - Mesoscale and Nanoscale Physics

Abstract

Precise shaping of coherent electron sources allows the controlled creation of wavepackets into a one dimensional (1D) quantum conductor. Periodic trains of Lorentzian pulses have been shown to induce minimal excitations without creating additional electron-hole pairs in a single non-interacting 1D electron channel. The presence of electron-electron (e-e) interactions dramatically affects the non-equilibrium dynamics of a 1D system. Here, we consider the intrinsic spectral properties of a helical liquid, with a pair of counterpropagating interacting channels, in the presence of time-dependent Lorentzian voltage pulses. We show that peculiar asymmetries in the behavior of the spectral function are induced by interactions, depending on the sign of the injected charges. Moreover, we discuss the robustness of the concept of minimal excitations in the presence of interactions, where the link with excess noise is no more straightforward. Finally, we propose a scanning tunneling microscope setup to spectroscopically access and probe the non-equilibrium behavior induced by the voltage drive and e-e interactions. This allows a diagnosis of fractional charges in a correlated quantum spin Hall liquid in the presence of time-dependent drives., Comment: 20 pages, 9 figures

Published

2019

36. Levitons in superconducting point contacts

Author

Acciai, Matteo, Ronetti, Flavio, Ferraro, Dario, Rech, Jérôme, Jonckheere, Thibaut, Sassetti, Maura, and Martin, Thierry

Subjects

Condensed Matter - Mesoscale and Nanoscale Physics

Abstract

We investigate the transport properties of a superconducting quantum point contact in the presence of an arbitrary periodic drive. In particular, we calculate the dc current and noise in the tunnel limit, obtaining general expressions in terms of photoassisted probabilities. Interesting features can be observed when the frequency is comparable to the gap. Here, we show that quantized Lorentzian pulses minimize the excess noise, further strengthening the hierarchy among different periodic drives observed in the electron quantum optics domain. In this regime, the excess noise is directly connected to the overlap between electron and hole energy distributions driven out of equilibrium by the applied voltage. In the adiabatic limit, where the frequency of the drive is very small compared to the superconducting gap, we recover the conventional Shapiro-spikes physics in the supercurrent., Comment: 9 pages, 5 figures

Published

2019

37. Optimal work-to-work conversion of a nonlinear quantum brownian duet

Author

Carrega, Matteo, Sassetti, Maura, and Weiss, Ulrich

Subjects

Condensed Matter - Mesoscale and Nanoscale Physics, Quantum Physics

Abstract

Performances of work-to-work conversion are studied for a dissipative nonlinear quantum system with two isochromatic phase-shifted drives. It is shown that for weak Ohmic damping simultaneous maximization of efficiency with finite power yield and low power fluctuations can be achieved. Optimal performances of these three quantities are accompanied by a shortfall of the trade-off bound recently introduced for classical thermal machines. This bound can be undercut down to zero for sufficiently low temperature and weak dissipation, where the non-Markovian quantum nature dominates. Analytic results are given for linear thermodynamics. These general features can persist in the nonlinear driving regime near to a maximum of the power yield and a minimum of the power fluctuations. This broadens the scope to a new operation field beyond linear response., Comment: 8 pages, 3 figures

Published

2019

38. Hong-Ou-Mandel heat noise in the quantum Hall regime

Author

Ronetti, Flavio, Vannucci, Luca, Ferraro, Dario, Jonckheere, Thibaut, Rech, Jérôme, Martin, Thierry, and Sassetti, Maura

Subjects

Condensed Matter - Mesoscale and Nanoscale Physics

Abstract

We investigate heat current fluctuations induced by a periodic train of Lorentzian-shaped pulses, carrying an integer number of electronic charges, in a Hong-Ou-Mandel interferometer implemented in a quantum Hall bar in the Laughlin sequence. We demonstrate that the noise in this collisional experiment cannot be reproduced in a setup with a single drive, in contrast to what is observed in the charge noise case. Nevertheless, the simultaneous collision of two identical levitons always leads to a total suppression even for the Hong-Ou-Mandel heat noise at all filling factors, despite the presence of emergent anyonic quasi-particle excitations in the fractional regime. Interestingly, the strong correlations characterizing the fractional phase are responsible for a remarkable oscillating pattern in the HOM heat noise, which is completely absent in the integer case. These oscillations can be related to the recently predicted crystallization of levitons in the fractional quantum Hall regime., Comment: 18 pages, 4 figures

Published

2018

39. Anomalous supercurrent and diode effect in locally perturbed topological Josephson junctions

Author

Fracassi, Samuele, primary, Traverso, Simone, additional, Traverso Ziani, Niccolo, additional, Carrega, Matteo, additional, Heun, Stefan, additional, and Sassetti, Maura, additional

Published

2024

40. Probing interactions via non-equilibrium momentum distribution and noise in integer quantum Hall systems at $\nu=2$

Author

Acciai, Matteo, Carrega, Matteo, Rech, Jérôme, Jonckheere, Thibaut, Martin, Thierry, and Sassetti, Maura

Subjects

Condensed Matter - Mesoscale and Nanoscale Physics

Abstract

We consider the excitation of single-electron wave packets by means of a time dependent voltage applied to the ballistic edge channels of the integer quantum Hall effect at filling factor $\nu=2$. Due to electron-electron interactions, fractional excitations emerge along the edge. Their detailed structure is analyzed by evaluating the nonequilibrium momentum distributions associated with the different edge channels. We provide results for a generic time-dependent drive both in the stationary regime and for intermediate times, where the overlap between fractionalized wave packets carries relevant information on interaction strength. As a particular example we focus on a Lorentzian drive, which provides a clear signature of the minimal excitations known as Levitons. Here, we argue that inner-channel fractionalized excitations can be exploited to extract information about inter-channel interactions. We further confirm this idea by calculating the zero frequency noise due to the partitioning of these excitations at a quantum point contact and we propose a measurable quantity as a tool to directly probe electron-electron interactions and determine the so-called mixing angle of copropagating quantum Hall channels., Comment: 14 pages, 7 figures

Published

2018

41. Z4 parafermions in one-dimensional fermionic lattices

Author

Calzona, Alessio, Meng, Tobias, Sassetti, Maura, and Schmidt, Thomas L.

Subjects

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

Abstract

Parafermions are emergent excitations which generalize Majorana fermions and are potentially relevant to topological quantum computation. Using the concept of Fock parafermions, we present a mapping between lattice $\mathbb{Z}_4$ parafermions and lattice spin-$1/2$ fermions which preserves the locality of operators with $\mathbb{Z}_4$ symmetry. Based on this mapping, we construct an exactly solvable, local, and interacting one-dimensional fermionic Hamiltonian which hosts zero-energy modes obeying parafermionic algebra. We numerically show that this parafermionic phase remains stable in a wide range of parameters, and discuss its signatures in the fermionic spectral function., Comment: 9 pages, 4 figures

Published

2018

42. Crystallization of Levitons in the fractional quantum Hall regime

Author

Ronetti, Flavio, Vannucci, Luca, Ferraro, Dario, Jonckheere, Thibaut, Rech, Jérôme, Martin, Thierry, and Sassetti, Maura

Subjects

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

Abstract

Using a periodic train of Lorentzian voltage pulses, which generates soliton-like electronic excitations called Levitons, we investigate the charge density backscattered off a quantum point contact in the fractional quantum Hall regime. We find a regular pattern of peaks and valleys, reminiscent of analogous self-organization recently observed for optical solitons in non-linear environments. This crystallization phenomenon is confirmed by additional side dips in the Hong-Ou-Mandel noise, a feature that can be observed in nowadays electron quantum optics experiments., Comment: 9 pages, 4 figures

Published

2017

43. Universal scaling of quench-induced correlations in a one-dimensional channel at finite temperature

Author

Calzona, Alessio, Gambetta, Filippo Maria, Carrega, Matteo, Cavaliere, Fabio, Schmidt, Thomas L., and Sassetti, Maura

Subjects

Condensed Matter - Strongly Correlated Electrons, Condensed Matter - Quantum Gases

Abstract

It has been shown that a quantum quench of interactions in a one-dimensional fermion system at zero temperature induces a universal power law $\propto t^{-2}$ in its long-time dynamics. In this paper we demonstrate that this behaviour is robust even in the presence of thermal effects. The system is initially prepared in a thermal state, then at a given time the bath is disconnected and the interaction strength is suddenly quenched. The corresponding effects on the long times dynamics of the non-equilibrium fermionic spectral function are considered. We show that the non-universal power laws, present at zero temperature, acquire an exponential decay due to thermal effects and are washed out at long times, while the universal behaviour $\propto t^{-2}$ is always present. To verify our findings, we argue that these features are also visible in transport properties at finite temperature. The long-time dynamics of the current injected from a biased probe exhibits the same universal power law relaxation, in sharp contrast with the non-quenched case which features a fast exponential decay of the current towards its steady value, and thus represents a fingerprint of quench-induced dynamics. Finally, we show that a proper tuning of the probe temperature, compared to that of the one-dimensional channel, can enhance the visibility of the universal power-law behaviour., Comment: 22 pages, 5 figures. Submission to SciPost

Published

2017

44. Photoassisted shot noise spectroscopy at fractional filling factor

Author

Vannucci, Luca, Ronetti, Flavio, Ferraro, Dario, Rech, Jérôme, Jonckheere, Thibaut, Martin, Thierry, and Sassetti, Maura

Subjects

Condensed Matter - Mesoscale and Nanoscale Physics

Abstract

We study the photoassisted shot noise generated by a periodic voltage in the fractional quantum Hall regime. Fluctuations of the current are due to the presence of a quantum point contact operating in the weak backscattering regime. We show how to reconstruct the photoassisted absorption and emission probabilities by varying independently the dc and ac contributions to the voltage drive. This is made possible by the peculiar power-law behavior of the tunneling rates in the chiral Luttinger liquid theory, which allow to approximate the typical infinite sums of the photoassisted transport formalism in a simple and particularly convenient way., Comment: 6 pages, 2 figures, Proceedings of LT28 (Gothenburg, Sweden)

Published

2017

45. Quench-induced entanglement and relaxation dynamics in Luttinger liquids

Author

Calzona, Alessio, Gambetta, Filippo Maria, Cavaliere, Fabio, Carrega, Matteo, and Sassetti, Maura

Subjects

Condensed Matter - Strongly Correlated Electrons, Condensed Matter - Quantum Gases

Abstract

We investigate the time evolution towards the asymptotic steady state of a one dimensional interacting system after a quantum quench. We show that at finite time the latter induces entanglement between right- and left- moving density excitations, encoded in their cross-correlators, which vanishes in the long-time limit. This behavior results in a universal time-decay in system spectral properties $ \propto t^{-2} $, in addition to non-universal power-law contributions typical of Luttinger liquids. Importantly, we argue that the presence of quench-induced entanglement clearly emerges in transport properties, such as charge and energy currents injected in the system from a biased probe, and determines their long-time dynamics. In particular, energy fractionalization phenomenon turns out to be a promising platform to observe the universal power-law decay $ \propto t^{-2} $ induced by entanglement and represents a novel way to study the corresponding relaxation mechanism., Comment: 11 pages, 3 figures

Published

2017

46. Charge and energy fractionalization mechanism in one-dimensional channels

Author

Acciai, Matteo, Calzona, Alessio, Dolcetto, Giacomo, Schmidt, Thomas L., and Sassetti, Maura

Subjects

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

Abstract

We study the problem of injecting single electrons into interacting one-dimensional quantum systems, a fundamental building block for electron quantum optics. It is well known that such injection leads to charge and energy fractionalization. We elucidate this concept by calculating the nonequilibrium electron distribution function in the momentum and energy domains after the injection of an energy-resolved electron. Our results shed light on how fractionalization occurs via the creation of particle-hole pairs by the injected electron. In particular, we focus on systems with a pair of counterpropagating channels, and we fully analyze the properties of each chiral fractional excitation which is created by the injection. We suggest possible routes to access their energy and momentum distribution functions in topological quantum Hall or quantum spin-Hall edge states., Comment: 13 pages, 6 figures

Published

2017

47. Minimal excitation states for heat transport in driven quantum Hall systems

Author

Vannucci, Luca, Ronetti, Flavio, Rech, Jérôme, Ferraro, Dario, Jonckheere, Thibaut, Martin, Thierry, and Sassetti, Maura

Subjects

Condensed Matter - Mesoscale and Nanoscale Physics

Abstract

We investigate minimal excitation states for heat transport into a fractional quantum Hall system driven out of equilibrium by means of time-periodic voltage pulses. A quantum point contact allows for tunneling of fractional quasi-particles between opposite edge states, thus acting as a beam splitter in the framework of the electron quantum optics. Excitations are then studied through heat and mixed noise generated by the random partitioning at the barrier. It is shown that levitons, the single-particle excitations of a filled Fermi sea recently observed in experiments, represent the cleanest states for heat transport, since excess heat and mixed shot noise both vanish only when Lorentzian voltage pulses carrying integer electric charge are applied to the conductor. This happens in the integer quantum Hall regime and for Laughlin fractional states as well, with no influence of fractional physics on the conditions for clean energy pulses. In addition, we demonstrate the robustness of such excitations to the overlap of Lorentzian wavepackets. Even though mixed and heat noise have nonlinear dependence on the voltage bias, and despite the non-integer power-law behavior arising from the fractional quantum Hall physics, an arbitrary superposition of levitons always generates minimal excitation states., Comment: 15 pages, 7 figures

Published

2017

48. Few-Body Precursors of Topological Frustration.

Author

De Filippi, Federico Raffaele, Mello, Antonio Francesco, Sacco Shaikh, Daniel, Sassetti, Maura, Traverso Ziani, Niccolò, and Grossi, Michele

Subjects

QUANTUM computing, QUANTUM theory, FRUSTRATION, PLAYGROUNDS, FORECASTING

Abstract

Spin 1/2 quantum spin chains represent the prototypical model for coupled two-level systems. Consequently, they offer a fertile playground for both fundamental and technological applications ranging from the theory of thermalization to quantum computation. Recently, it has been shown that interesting phenomena are associated to the boundary conditions imposed on the quantum spin chains via the so-called topological frustration. In this work, we analyze the effects of such frustration on a few-spin system, with a particular focus on the strong even–odd effects induced in the ground-state energy. We then implement a topologically frustrated quantum spin chain on a quantum computer to show that our predictions are visible on current quantum hardware platforms. [ABSTRACT FROM AUTHOR]

Published

2024

49. Qutrit quantum battery: Comparing different charging protocols

Author

Gemme, Giulia, primary, Grossi, Michele, additional, Vallecorsa, Sofia, additional, Sassetti, Maura, additional, and Ferraro, Dario, additional

Published

2024

50. Boosting energy transfer between quantum devices through spectrum engineering in the dissipative ultrastrong coupling regime

Author

Crescente, Alba, primary, Ferraro, Dario, additional, and Sassetti, Maura, additional

Published

2024