Your search keyword '"Venegas, P."' showing total 6 results

1. Vortex Dynamic Phases in Type II Superconducting Strips with Regular and Flattened Triangular Pinning Arrays.

Author

Verga, L. G., Vizarim, N. P., Carlone, M., and Venegas, P. A.

Subjects

SUPERCONDUCTIVITY, FLUX flow, ELECTROMAGNETS, MAGNETOMETERS, MAGNETIC fields

Abstract

The dynamic behavior of vortices in type II superconducting infinite strips is simulated with two types of triangular pinning lattices: the regular one and a flattened triangular array that mimics the vortex lattice in a superconducting strip in the absence of a pinning array. The calculations were made at zero temperature and perpendicular magnetic field. The size effects are investigated for several strip widths maintaining the density and size of pinning centers unchanged. A driving force is applied in the infinite direction to analyze the depinning process and the different dynamic regimes. For the regular triangular pinning lattice, we found that there is a great richness of vortex dynamical phases because depending on strip width, part of the vortices may stabilize in different interstitial positions and the depinning process depends on the commensurability of each vortex chain. For the flattened triangular lattice, the system exhibits one ordered moving phase for narrower strips and two moving phases for the larger strip. As the transport force increases, vortices in the larger strip go from a disordered to an ordered phase. Moreover, the flattened lattice shows a much higher critical depinning force than the regular one due to commensurability effects. [ABSTRACT FROM AUTHOR]

Published

2019

2. Surface Effects on the Dynamic Behavior of Vortices in Type II Superconducting Strips with Periodic and Conformal Pinning Arrays.

Author

Vizarim, N. P., Carlone, M., Verga, L. G., and Venegas, P. A.

Subjects

SUPERCONDUCTORS, MOLECULAR dynamics, VORTEX motion, FLUX pinning, MAGNETIC fields

Abstract

Using molecular dynamics techniques, we simulate the vortex behavior in a type II superconducting strip in the presence of triangular and two types of conformal pinning arrays, one with a pinning gradient perpendicular to the driving force (C1) and the other parallel (C2), at zero temperature. A transport force is applied in the infinite direction of the strip, and the magnetic field is increased until the rate between the density of vortices (nv) and pinning (np) reaches nv/np = 1.5. Our results show a monotonic increase, by steps, of the vortex density with the applied magnetic field. Besides, each pinning lattice presents a different vortex penetration delay. For the triangular pinning array, different than the case of infinite films, here the system exhibits only one pronounced depinning force peak at nv/np = 1. However, the depinning force peak is present for only one value of field, in the range of fields where nv/np = 1 is stable. For the case of conformal pinning arrays, in analogy to what is observed in infinite films, no commensurability depinning force peaks were found. In the present case, the C1 array is more efficient at low fields, all arrays are equivalent in the intermediate fields, and the C2 array is more efficient for high fields. We also show that for the C1 array at high fields, vortices depin following the conformal arches, from the edge to the center. For the C2 array, the depinning force is higher when compared to that of C1, because this particular conformal structure prevents the formation of easy vortex flow channels. [ABSTRACT FROM AUTHOR]

Published

2018

3. The Effects of Pinning on Critical Currents of Superconducting Films.

Author

Simões, R., Venegas, P., and Mello, D.

Subjects

*CRITICAL current density (Superconductivity), *SUPERCONDUCTING thin films, *DISLOCATION pinning, *MOLECULAR dynamics, *SIMULATION methods & models, *ANISOTROPY

Abstract

Using molecular dynamics simulations, we analyze the effects of artificial periodic arrays of pinning sites on the critical current of superconducting thin films as a function of vortex density. We analyze two types of periodic pinning array: hexagonal and Kagomé. For the Kagome pinning network we make calculations using two directions of transport current: along and perpendicular to the main axis of the lattice. Our results show that the hexagonal pinning array presents higher critical currents than the Kagomé and random pinning configuration for all vortex densities. In addition, the Kagomé networks show anisotropy in their transport properties. [ABSTRACT FROM AUTHOR]

Published

2013

4. Critical Currents and Melting Temperature of a Two-Dimensional Vortex Lattice with Periodic Pinning.

Author

Verga, L., Bonilha, M., Carlone, M., and Venegas, P.

Subjects

CRITICAL currents, VORTEX lattice method, FLUX pinning, ANISOTROPY, TEMPERATURE

Abstract

The critical current and melting temperature of a vortex system are analyzed. Calculations are made for a two-dimensional film at finite temperature with two kinds of periodic pinning: hexagonal and Kagomé. A transport current parallel and perpendicular to the main axis of the pinning arrays is applied and molecular dynamics simulations are used to calculate the vortex velocities to obtain the critical currents. The structure factor and displacements of vortices at zero transport current are used to obtain the melting temperature for both pinning arrays. The critical currents are higher for the hexagonal pinning lattice and anisotropic for both pinning arrays. This anisotropy is stronger with temperature for the hexagonal array. For the Kagomé pinning lattice, our analysis shows a multi stage phase melting; that is, as we increase the temperature, each different dynamic phase melts before reaching the melting temperature. Both the melting temperature and critical currents are larger for the hexagonal lattice, indicating the role for the interstitial vortices in decreasing the pinning strength. [ABSTRACT FROM AUTHOR]

Published

2013

5. Anisotropy in the Transport Properties of Type II Superconducting Films with Periodic Pinning.

Author

Verga, L., Silva, M., Simões, R., Mello, D., and Venegas, P.

Subjects

ANISOTROPY, ANISOTROPIC conductive films, TYPE II superconductors, SUPERCONDUCTIVITY, CRITICAL current measurement

Abstract

Using numerical simulations, we analyze the anisotropy effects in the critical currents and dynamical properties of vortices in a thin superconducting film submitted to hexagonal and Kagomé periodical pinning arrays. The calculations are performed at zero temperature, for transport currents parallel and perpendicular to the main axis of the lattice, and parallel to the diagonal axis of the rhombic unit cell. We show that the critical currents and dynamic properties are anisotropic for both pinning arrays and all directions of the transport current. The anisotropic effects are more significant just above the critical current and disappear with higher values of current and both pinning arrays. The dynamical phases for each case and a wide range of transport forces are analyzed. [ABSTRACT FROM AUTHOR]

Published

2013

6. Role of Interstitial Pinning in the Dynamical Phases of Vortices in Superconducting Films.

Author

Simões, R., Venegas, P., and Mello, D.

Subjects

*SPHEROMAKS, *SUPERCONDUCTING films, *ANISOTROPY, *LONGITUDINAL Doppler effect, *TRANSVERSE Doppler effect

Abstract

We analyze the vortex dynamics in superconducting thin films with a periodic array of pinning centers. In particular, we study the effect of anisotropy for a Kagomé pinning network when longitudinal and transverse transport currents are applied. By solving the equations of motion for the vortex array numerically at zero temperature, we find different phases for the vortex dynamics, depending on the pinning and driving force. An unusual sequence of peaks for driving force along and perpendicular to the main lattice axes is observed for the differential resistance, reflecting the anisotropy of the transport properties and the complex behavior of the vortex system. This behavior may be understood in terms of interstitial pinning vacancies, which create channels of vortices with different pinning strengths. [ABSTRACT FROM AUTHOR]

Published

2013