220 research outputs found
Multiple quasiparticle Hall spectroscopy investigated with a resonant detector
We investigate the finite frequency (f.f.) noise properties of edge states in
the quantum Hall regime. We consider the measurement scheme of a resonant
detector coupled to a quantum point contact in the weak-backscattering limit. A
detailed analysis of the difference between the "measured" noise, due to the
presence of the resonant detector, and the symmetrized f.f. noise is presented.
We discuss both the Laughlin and Jain sequences, studying the tunnelling
excitations in these hierarchical models. We argue that the measured noise can
better distinguish between the different excitations in the tunnelling process
with respect to the symmetrized f.f. counterpart in an experimentally relevant
range of parameters. Finally, we illustrate the effect of the detector
temperature on the sensibility of this measure.Comment: 24 pages, 8 figure
Theory of Coulomb drag for massless Dirac fermions
Coulomb drag between two unhybridized graphene sheets separated by a
dielectric spacer has recently attracted considerable theoretical interest. We
first review, for the sake of completeness, the main analytical results which
have been obtained by other authors. We then illustrate pedagogically the
minimal theory of Coulomb drag between two spatially-separated two-dimensional
systems of massless Dirac fermions which are both away from the
charge-neutrality point. This relies on second-order perturbation theory in the
screened interlayer interaction and on Boltzmann transport theory. In this
theoretical framework and in the low-temperature limit, we demonstrate that, to
leading (i.e. quadratic) order in temperature, the drag transresistivity is
completely insensitive to the precise intralayer momentum-relaxation mechanism
(i.e. to the functional dependence of the scattering time on energy). We also
provide analytical results for the low-temperature drag transresistivity for
both cases of "thick" and "thin" spacers and for arbitrary values of the
dielectric constants of the media surrounding the two Dirac-fermion layers.
Finally, we present numerical results for the low-temperature drag
transresistivity in the case in which one of the media surrounding the
Dirac-fermion layers has a frequency-dependent dielectric constant. We conclude
by suggesting an experiment that can potentially allow for the observation of
departures from the canonical Fermi-liquid quadratic-in-temperature behavior of
the transresistivity.Comment: 20 pages, 4 figure
Anomalous charge tunneling in the fractional quantum Hall edge states at filling factor \nu = 5/2
We explain effective charge anomalies recently observed for fractional
quantum Hall edge states at [M. Dolev, Y. Gross, Y. C. Chung, M.
Heiblum, V. Umansky, and D. Mahalu, Phys.Rev. B. \textbf{81}, 161303(R)
(2010)]. The experimental data of differential conductance and excess noise are
fitted, using the anti-Pfaffian model, by properly take into account
renormalizations of the Luttinger parameters induced by the coupling of the
system with an intrinsic noise. We demonstrate that a peculiar
agglomerate excitation with charge , double of the expected charge,
dominates the transport properties at low energies.Comment: 5 pages, 2 figure
Monitoring Network Flows in Containerized Environments
With the progressive implementation of digital services over virtualized infrastructures and smart devices, the inspection of network traffic becomes more challenging than ever, because of the difficulty to run legacy cybersecurity tools in novel cloud models and computing paradigms. The main issues concern i) the portability of the service across heterogeneous public and private infrastructures, that usually lack hardware and software acceleration for efficient packet processing, and ii) the difficulty to integrate monolithic appliances in modular and agile containerized environments. In this Chapter, we investigate the usage of the extended Berkeley Packet Filter (eBPF) for effective and efficient packet inspection in virtualized environments. Our preliminary implementation demonstrates that we can achieve the same performance as well-known packet inspection tools, but with far less resource consumption. This motivates further research work to extend the capability of our framework and to integrate it in Kubernetes
Polarized heat current generated by quantum pumping in two-dimensional topological insulators
We consider transport properties of a two dimensional topological insulator
in a double quantum point contact geometry in presence of a time-dependent
external field. In the proposed setup an external gate is placed above a single
constriction and it couples only with electrons belonging to the top edge. This
asymmetric configuration and the presence of an ac signal allow for a quantum
pumping mechanism, which, in turn, can generate finite heat and charge currents
in an unbiased device configuration. A microscopic model for the coupling with
the external time-dependent gate potential is developed and the induced finite
heat and charge currents are investigated. We demonstrate that in the
non-interacting case, heat flow is associated with a single spin component, due
to the helical nature of the edge states, and therefore a finite and polarized
heat current is obtained in this configuration. The presence of e-e
interchannel interactions strongly affects the current signal, lowering the
degree of polarization of the system. Finally, we also show that separate heat
and charge flows can be achieved, varying the amplitude of the external gate.Comment: 13 pages, 5 figure
Environmental induced renormalization effects in quantum Hall edge states
We propose a general mechanism for renormalization of the tunneling exponents
in edge states of the fractional quantum Hall effect. Mutual effects of the
coupling with out-of-equilibrium 1/f noise and dissipation are considered both
for the Laughlin sequence and for composite co- and counter-propagating edge
states with Abelian or non-Abelian statistics. For states with
counter-propagating modes we demonstrate the robustness of the proposed
mechanism in the so called disorder-dominated phase. Prototypes of these
states, such as \nu=2/3 and \nu=5/2, are discussed in detail and the rich
phenomenology induced by the presence of a noisy environment is presented. The
proposed mechanism justifies the strong renormalizations reported in many
experimental observations carried out at low temperatures. We show how
environmental effects could affect the relevance of the tunneling excitations,
leading to important implications in particular for the \nu=5/2 case.Comment: 14 pages, 4 figure
An architecture to manage security services for cloud applications
The uptake of virtualization and cloud technologies has pushed novel development and operation models for the software, bringing more agility and automation. Unfortunately, cyber-security paradigms have not evolved at the same pace and are not yet able to effectively tackle the progressive disappearing of a sharp security perimeter. In this paper, we describe a novel cyber-security architecture for cloud-based distributed applications and network services. We propose a security orchestrator that controls pervasive, lightweight, and programmable security hooks embedded in the virtual functions that compose the cloud application, pursuing better visibility and more automation in this domain. Our approach improves existing management practice for service orchestration, by decoupling the management of the business logic from that of security. We also describe the current implementation stage for a programmable monitoring, inspection, and enforcement framework, which represents the ground technology for the realization of the whole architecture
Programmable data gathering for detecting stegomalware
The 'arm race' against malware developers requires to collect a wide variety of performance measurements, for instance to face threats leveraging information hiding and steganography. Unfortunately, this process could be time-consuming, lack of scalability and cause performance degradations within computing and network nodes. Moreover, since the detection of steganographic threats is poorly generalizable, being able to collect attack-independent indicators is of prime importance. To this aim, the paper proposes to take advantage of the extended Berkeley Packet Filter to gather data for detecting stegomalware. To prove the effectiveness of the approach, it also reports some preliminary experimental results obtained as the joint outcome of two H2020 Projects, namely ASTRID and SIMARGL
Hybrid quantum thermal machines with dynamical couplings
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. Owing to its versatility and tunability, our model may be of interest for engineering thermodynamic tasks and for thermal management in quantum technologies
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