737 research outputs found
P-wave Cooper pair splitting
Splitting of Cooper pairs has recently been realized experimentally for
s-wave Cooper pairs. A split Cooper pair represents an entangled two-electron
pair state which has possible application in on-chip quantum computation.
Likewise the spin-activity of interfaces in nanoscale tunnel junctions has been
investigated theoretically and experimentally in recent years. However, the
possible implications of spin-active interfaces in Cooper pair splitters so far
have not been investigated. We analyse the current and the cross correlation of
currents in a superconductor ferromagnet beamsplitter including spin-active
scattering. Using the Hamiltonian formalism we calculate the cumulant
generating function of charge transfer. As a first step, we discuss
characteristics of the conductance for crossed Andreev reflection in
superconductor ferromagnet beamsplitters with s-wave and p-wave superconductors
and no spin-active scattering. In a second step, we consider spin-active
scattering and show how to realize p-wave splitting only using a s-wave
superconductor via the process of spin-flipped crossed Andreev reflection. We
present results for the conductance and cross correlations. Spin-activity of
interfaces in Cooper pair splitters allows for new features in ordinary s-wave
Cooper pair splitters, that can otherwise only be realised by using p-wave
superconductors. In particular it provides access to Bell states different from
the typical spin singlet state.Comment: 7 pages, 2 figures, accepted by Beilstein Journal of Nanotechnology,
references correcte
Charge transfer statistics and entanglement in normal-quantum dot-superconductor hybrid structures
We analyze the full counting statistics (FCS) of a single-site quantum dot
coupled to multiple metallic electrodes in the normal state and a
superconductor for arbitrary transmission. We present an analytical solution of
the problem taking into account the full energy dependence of the transmission
coefficient. We identify two transport processes as sources of entanglement
between the current carriers by observing positive cross current correlations.
Furthermore, we consider ferromagnetic electrodes and show how they can be used
as detectors in experiments violating the Bell-Clauser-Horne-Shimony-Holt
inequality.Comment: 6 pages, 3 figures, typos fixed, references adde
Full counting statistics of interacting quantum dots contacted by a normal metal and a superconductor
We investigate the effects of Coulomb interaction on charge transfer through
a quantum dot attached to a normal and a superconducting lead. While for
voltages much larger than the gap we recover the usual result for normal
conductors, for voltages much smaller than the gap superconducting correlations
lead to a drastically different behavior. Especially, the usual charge doubling
in the normal case is reflected in the occurence of quartets due to the onsite
interaction.Comment: 6 pages, 3 figures, accepted by EP
Nanotransformation and current fluctuations in exciton condensate junctions
We analyze the nonlinear transport properties of a bilayer exciton condensate
that is contacted by four metallic leads by calculating the full counting
statistics of electron transport for arbitrary system parameters. Despite its
formal similarity to a superconductor the transport properties of the exciton
condensate turn out to be completely different. We recover the generic features
of exciton condensates such as counterpropagating currents driven by excitonic
Andreev reflections and make predictions for nonlinear transconductance between
the layers as well as for the current (cross)correlations and generalized
Johnson-Nyquist relationships. Finally, we explore the possibility of
connecting another mesoscopic system (in our case a quantum point contact) to
the bottom layer of the exciton condensate and show how the excitonic Andreev
reflections can be used for transforming voltage at the nanoscale.Comment: 5 pages, 4 figures, accepted by PR
An integrated approach for analysing and assessing the performance of virtual learning groups
Collaborative distance learning involves a variety of elements and factors that have to be considered and measured in order to analyse and assess group and individual performance more effectively and objectively. This paper presents an approach that integrates qualitative, social network analysis (SNA) and quantitative techniques for evaluating online collaborative learning interactions. Integration of various different data sources, tools and techniques provides a more complete and robust framework for group modelling and guarantees a more efficient evaluation of group effectiveness and individual competence. Our research relies on the analysis of a real, long-term, complex collaborative experience, which is initially evaluated in terms of principled criteria and a basic qualitative process. At the end of the experience, the coded student interactions are further analysed through the SNA technique to assess participatory aspects, identify the most effective groups and the most prominent actors. Finally, the approach is contrasted and completed through a statistical technique which sheds more light on the results obtained that far. The proposal draws a well-founded line toward the development of a principled framework for the monitoring and analysis of group interaction and group scaffolding which can be considered a major issue towards the actual application of the CSCL proposals to real classrooms.Peer ReviewedPostprint (author's final draft
Kondo effect and spin-active scattering in ferromagnet-superconductor junctions
We study the interplay of superconducting and ferromagnetic correlations on
charge transport in different geometries with a focus on both a quantum point
contact as well as a quantum dot in the even and the odd state with and without
spin-active scattering at the interface. In order to obtain a complete picture
of the charge transport we calculate the full counting statistics in all cases
and compare the results with experimental data. We show that spin-active
scattering is an essential ingredient in the description of quantum point
contacts. This holds also for quantum dots in an even charge state whereas it
is strongly suppressed in a typical Kondo situation. We explain this feature by
the strong asymmetry of the hybridisations with the quantum dot and show how
Kondo peak splitting in a magnetic field can be used for spin filtering. For
the quantum dot in the even state spin-active scattering allows for an
explanation of the experimentally observed mini-gap feature.Comment: 14 pages, 7 figures, accepted by PR
Systems and methods for correcting optical reflectance measurements
We disclose measurement systems and methods for measuring analytes in target regions of samples that also include features overlying the target regions. The systems include: (a) a light source; (b) a detection system; (c) a set of at least first, second, and third light ports which transmit light from the light source to a sample and receive and direct light reflected from the sample to the detection system, generating a first set of data including information corresponding to both an internal target within the sample and features overlying the internal target, and a second set of data including information corresponding to features overlying the internal target; and (d) a processor configured to remove information characteristic of the overlying features from the first set of data using the first and second sets of data to produce corrected information representing the internal target
Impact of hydrogen on the high cycle fatigue behaviour of Inconel 718 in asymmetric push–pull mode at room temperature
AbstractThe influence of hydrogen on the high cycle fatigue (HCF) behaviour of Inconel 718 has been studied at room temperature in asymmetric push–pull mode using an ultrasonic HCF test rig. Fatigue tests have been carried out in gaseous hydrogen (GH2) and in Ar at a pressure of 30MPa. Oscillating stresses with amplitudes (σa) up to 450MPa and mean stresses (σm) up to 600MPa have been applied. For a given σa and σm, the lifetime in Ar is generally longer than in GH2, which is explained by a hydrogen-induced embrittlement of the material. For a constant σa of 218MPa, the lifetime in Ar and in GH2 is very similar for high σm, but the difference in lifetime increases as the mean stress decreases. An approach is presented to describe the number of cycles to failure Nf as a function of σa and σm.Microstructural analysis has been performed on the specimens tested at σa=218MPa and two values of σm (300MPa and 600MPa). SEM analyses of the fracture surfaces of these samples indicate embrittlement of the material when tested in hydrogen atmosphere
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