Your search keyword '"Mesoscopic and nanoscale systems"' showing total 4 results

1. Development of a Josephson vortex two-state system based on a confocal annular Josephson junction

Author

Monaco, Roberto, Mygind, Jesper, Koshelets, Valery P., Monaco, Roberto, Mygind, Jesper, and Koshelets, Valery P.

Abstract

We report theoretical and experimental work on the development of a Josephson vortex two-state system based on a confocal annular Josephson tunnel junction (CAJTJ). The key ingredient of this geometrical configuration is a periodically variable width that generates a spatial vortex potential with bistable states. This intrinsic vortex potential can be tuned by an externally applied magnetic field and tilted by a bias current. The two-state system is accurately modeled by a one-dimensional sine-Gordon like equation by means of which one can numerically calculate both the magnetic field needed to set the vortex in a given state as well as the vortex-depinning currents. Experimental data taken at on high-quality Nb/Al–AlOx/Nb CAJTJs with an individual trapped fluxon advocate the presence of a robust and finely tunable double-well potential for which reliable manipulation of the vortex state has been classically demonstrated. The vortex is prepared in a given potential by means of an externally applied magnetic field, while the state readout is accomplished by measuring the vortex-depinning current in a small magnetic field. Our proof of principle experiment convincingly demonstrates that the proposed vortex two-state system based on CAJTJs is robust and workable.

Published

2018

2. Current distributions in stripe Majorana junctions

Author

Ministerio de Economía y Competitividad (España), Universidad de Las Islas Baleares, Osca, Javier, Serra, Llorenç, Ministerio de Economía y Competitividad (España), Universidad de Las Islas Baleares, Osca, Javier, and Serra, Llorenç

Abstract

We calculate current and density distributions in stripe (2D planar) junctions between normal and Majorana nanowires having a finite (y) transverse length. In presence of a magnetic field with vertical and in-plane components, the y-symmetry of the charge current distribution in the normal lead changes strongly across the Majorana phase transition: from center-symmetric if a Majorana mode is present to laterally-shifted (as expected by the Hall effect) if the field is tilted such as to destroy the Majorana mode due to the projection rule. We compare quasi-particle and charge distributions of current and density, as well as spin magnetizations. The Majorana mode causes opposite spin accumulations on the transverse sides of the junction and the emergence of a spin current.

Published

2017

3. Fermi-velocity renormalization due to interactions in graphene: the influence of a weak magnetic field

Author

Menezes, N., Alves, Van Sergio, de Morais Smith, C., Menezes, N., Alves, Van Sergio, and de Morais Smith, C.

Abstract

The experimental observation of the renormalization of the Fermi velocity as a function of doping has been a landmark for confirming the importance of electronic interactions in graphene. Although the experiments were performed in the presence of a perpendicular magnetic field B, the measurements are well described by a renormalization-group (RG) theory that did not include it. Here we clarify this issue and show that for the weak magnetic fields at which the experiments are performed, there is no change in the renormalization-group functions. Our calculations are carried out in the framework of the Pseudo-quantum electrodynamics (PQED) formalism, which accounts for dynamical interactions. We include only the linear dependence in B, and solve the problem using two different parametrizations, the Feynman and the Schwinger one. We confirm the results obtained earlier within the RG procedure and show that, within linear order in the magnetic field, the only contribution to the renormalization of the Fermi velocity arises due to interactions.

Published

2016

4. Cross correlations in mesoscopic charge detection

Author

Ministerio de Economía y Competitividad (España), Kohler, Sigmund, Ministerio de Economía y Competitividad (España), and Kohler, Sigmund

Abstract

We study a tunnel contact that acts as charge detector for a single-electron transistor (SET) focusing on correlations between the detector curre nt and the current through the SET. This system can be described fully by a Markovian master equation for the SET, while electron tunneling in the charge monitor represents a process with a stochastic rate, which can be solved exactly. It turns out that current monitoring is possible as long as the detector current correlates with the currents through either SET barrier. By contrast, correlations with the effective current according to the Ramo-Shockley theorem are not essential. Moreover, we propose the mea surement of the SET barrier capacitances.

Published

2013