Your search keyword '"Cataudella, Vittorio"' showing total 6 results

1. Environment induced dynamical quantum phase transitions in two-qubit Rabi model.

Author

Di Bello, Grazia, Ponticelli, Andrea, Pavan, Fabrizio, Cataudella, Vittorio, De Filippis, Giulio, de Candia, Antonio, and Perroni, Carmine Antonio

Subjects

QUANTUM phase transitions, QUANTUM states, QUBITS, THERMODYNAMIC equilibrium, DYNAMICAL systems

Abstract

Quantum states beyond thermodynamic equilibrium represent fascinating and cutting-edge research. However, the behavior of dynamical quantum phase transitions in complex open quantum systems remains poorly understood. Here, using state-of-the-art numerical approaches, we show that by quenching the qubits-oscillator coupling in a dissipative two-qubit Rabi model, the system undergoes dynamical quantum phase transitions. These transitions are characterized by kinks in the Loschmidt echo rate function at parameter values close to a thermodynamic quantum phase transition and are associated with distinct entanglement features. The two classes of critical phenomena depend on qubit interactions and entanglement, revealing different behaviors of the critical exponent of the first kink of the Loschmidt echo for interacting versus non-interacting qubits. This research enhances our understanding of non-equilibrium quantum systems and offers potential applications in quantum sensing and metrology, as it examines how dynamical transitions can enhance the sensitivity of the Loschmidt echo to the quench parameters. Dynamical quantum phase transitions can be observed when time is treated as a control parameter in non-equilibrium quantum systems. The authors show that quenching the qubits-oscillator coupling in a dissipative two-qubit system leads to different transitions depending on interactions and entanglement, with promising applications in quantum sensing and metrology. [ABSTRACT FROM AUTHOR]

Published

2024

2. Editorial: innovative quantum materials.

Author

Cataudella, Vittorio, Lucignano, Procolo, and Perroni, Carmine Antonio

Abstract

Quantum Materials are materials where the manifestation of the quantum mechanical nature of matter constituents, which comes into evidence at the macroscopic scale, is used to obtain new functionalities. The study of quantum materials is relevant both on the fundamental and on the applied side. Indeed, this class of materials provides a common thread between physics, materials science and engineering. The focus is on emergent excitations, such as Dirac and Majorana fermions. In particular, it analyzes their sensitivity to external perturbations, such as electric and magnetic fields, and boundary conditions that can be controlled by surface/edge terminations, defect states and nanostructuring. The topical issue provides a broad description of innovative quantum materials discussing a variety of different phenomena: (1) interference phenomena in quantum devices made up of a topological insulator, (2) bound states in finite length nanowires with an inhomogeneous spin–orbit coupling profile relevant for Majorana physics, (3) sensitivity of graphene transport properties to defect states and edge functionalization, (4) role of Moiré phonons on the energy properties of twisted bilayer graphene at the magic angle important for van der Waals materials, (5) emergent spin excitations and anisotropic magnetotransport properties in iridates, (6) magnetoelectric couplings and improper magnetoelectric behavior in manganites significant for the realization of novel spintronic devices. [ABSTRACT FROM AUTHOR]

Published

2021

3. Post-Deposition Wetting and Instabilities in Organic Thin Films by Supersonic Molecular Beam Deposition.

Author

Chiarella, Fabio, Perroni, Carmine Antonio, Chianese, Federico, Barra, Mario, De Luca, Gabriella Maria, Cataudella, Vittorio, and Cassinese, Antonio

Abstract

We discuss the formation and post-deposition instability of nanodrop-like structures in thin films of PDIF-CN2 (a perylene derivative) deposited via supersonic molecular beam deposition technique on highly hydrophobic substrates at room temperature. The role of the deposition rate on the characteristic lengths of the organic nanodrops has been investigated by a systematic analysis of atomic force microscope images of the thin films and through the use of the height-height correlation function. The nanodrops appear to be a metastable configuration for the freshly-deposited films. For this reason, post-deposition wetting effect has been examined with unprecedented accuracy throughout a year of experimental observations. The observed time scales, from few hours to months, are related to the growth rate, and characterize the thin films morphological reordering from three-dimensional nanodrops to a well-connected terraced film. While the interplay between adhesion and cohesion energies favors the formation of 3D-mounted structures during the growth, wetting phenomenon following the switching off of the molecular flux is found to be driven by an instability. A slow rate downhill process survives at the molecular flux shutdown and it is accompanied and maybe favored by the formation of a precursor layer composed of more lying molecules. These results are supported by simulations based on a non-linear stochastic model. The instability has been simulated, for both the growth and the post-growth evolution. To better reproduce the experimental data it is needed to introduce a surface equalizer term characterized by a relaxation time taking into account the presence of a local mechanism of molecular correlation. [ABSTRACT FROM AUTHOR]

Published

2018

4. Detection of Zak phases and topological invariants in a chiral quantum walk of twisted photons.

Author

Cardano, Filippo, D'Errico, Alessio, Dauphin, Alexandre, Maffei, Maria, Piccirillo, Bruno, de Lisio, Corrado, De Filippis, Giulio, Cataudella, Vittorio, Santamato, Enrico, Marrucci, Lorenzo, Lewenstein, Maciej, and Massignan, Pietro

Abstract

Topological insulators are fascinating states of matter exhibiting protected edge states and robust quantized features in their bulk. Here we propose and validate experimentally a method to detect topological properties in the bulk of one-dimensional chiral systems. We first introduce the mean chiral displacement, an observable that rapidly approaches a value proportional to the Zak phase during the free evolution of the system. Then we measure the Zak phase in a photonic quantum walk of twisted photons, by observing the mean chiral displacement in its bulk. Next, we measure the Zak phase in an alternative, inequivalent timeframe and combine the two windings to characterize the full phase diagram of this Floquet system. Finally, we prove the robustness of the measure by introducing dynamical disorder in the system. This detection method is extremely general and readily applicable to all present one-dimensional platforms simulating static or Floquet chiral systems. [ABSTRACT FROM AUTHOR]

Published

2017

5. Statistical moments of quantum-walk dynamics reveal topological quantum transitions.

Author

Cardano, Filippo, Maffei, Maria, Massa, Francesco, Piccirillo, Bruno, de Lisio, Corrado, De Filippis, Giulio, Cataudella, Vittorio, Santamato, Enrico, and Marrucci, Lorenzo

Published

2016

6. Witnessing the formation and relaxation of dressed quasi-particles in a strongly correlated electron system.

Author

Novelli, Fabio, De Filippis, Giulio, Cataudella, Vittorio, Esposito, Martina, Vergara, Ignacio, Cilento, Federico, Sindici, Enrico, Amaricci, Adriano, Giannetti, Claudio, Prabhakaran, Dharmalingam, Wall, Simon, Perucchi, Andrea, Dal Conte, Stefano, Cerullo, Giulio, Capone, Massimo, Mishchenko, Andrey, Grüninger, Markus, Nagaosa, Naoto, Parmigiani, Fulvio, and Fausti, Daniele

Published

2014