ZFC process in 2+1 and 3+1 multi-band superconductor

Aguirre, C. A.; Arruda, A.S. de; Faundez, Julian; Barba-Ortega, J.

doi:10.1016/j.physb.2021.413032

Cited by 15 publications

(10 citation statements)

References 21 publications

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“…Finally, the plausibility of the formation of a fractional quantum in view of the previous theories are discussed. Several theories exist to predict a fractional flux quantum and a fractional vortex in the bilayer and multicomponent superconductors with a finite quadratic Josephson interaction between two components [7,[30][31][32][33][34][35][36][37][38][39][40][41][42]. Although these theories have not been experimentally confirmed (in other words, the situations discussed in these theories…”

Section: Resultsmentioning

confidence: 99%

Phase shifter based on an ultrathin superconducting bilayer with a through-hole for a superconducting device

Ishizu

Yamamori

Arisawa

et al. 2021

Preprint

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Applying a radian phase shift other than 2π is a key issue for superconducting circuits, such as flux qubits. The magnetic flux is useful when generating a phase shift. However, a quantized magnetic flux accompanying a trapped vortex in a superconductor does not have a phase shifter function. The magnetic flux generated by an external field generates noise. In this study, we propose a phase bias system that does not require an external field during operation. We confirm the phase shift of a direct current superconducting interference device (SQUID) placed on an ultrathin superconducting Nb bilayer with a through-hole by cooling it to a temperature below the superconducting transition temperature with an external field. Although the cause of the phase shift in our system is unclear, we believe that it may be caused by a fractional quantum in the bilayer. When the SQUID is replaced by a qubit, the phase shift can be applied to a phase bias.

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Section: Resultsmentioning

confidence: 99%

Phase shifter based on an ultrathin superconducting bilayer with a through-hole for a superconducting device

Ishizu

Yamamori

Arisawa

et al. 2021

Preprint

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“…( 5) does not exist, leaving only a superconducting condensate ψ 1 . For the computational mesh we use ∆x = ∆y = 0.1 [13,15,16,32]. In the field cooling processes simulations for we take T = 0.1.…”

Section: Theoretical Formalismmentioning

confidence: 99%

“…This field has developed since its discovery in 1908 by H. Onnes, G. Holts and J. Flint [6], encompassing different branches that they contemplate, mesoscopic superconductivity [7,8], topological [9][10][11], multi-band [12,13], frustrated superconductivity [14] and its applications in electronic devices reaffirm its importance in the advancement of new technologies based on vortex control [15,16], Magnons [17] or Hopfios [18], not without first mentioning the discovery of superconductivity in ferromagnetic systems [19]. In general, until now, there are three specific theoretical models for to study the superconducting state.…”

Section: Introductionmentioning

confidence: 99%

“…The second method, based on extensions of the Bardeen-Cooper-Schrieffer (BCS) theory, has the ability to study superconductivity on a mesoscopic scale, giving excellent results compared to experimental ones [24,25], but it neglects the geometry of the sample itself, besides that its solution is based mainly on the diagonalization of the Bogoliubov de Gennes Hamiltonian, a main problem is that it presents long computation times [26]. Now, the third form of study is based on the extension of the second order transition theory, proposed by L. Landau to superconducting systems, accounting for a parameter of order ψ or pseudo-wave function that describes the superconducting state in the mesoscopic regime (d ≈ ξ(0)) [27,28]. The latter is widely used † cristian@fisica.ufmt.br for the study of the dynamics of vortices in different geometries, which are mainly regular domains (circles, squares/rectangles or triangles) [29][30][31], due to the high convergence times and the difficulty of applying boundary conditions in domains with geometries different from those mentioned above, little or no other types of geometries are discussed.…”

Section: Introductionmentioning

confidence: 99%

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Vortex state in a superconducting mesoscopic irregular octagon

Aguirre,

Faundez,

Barba-Ortega

2021

Preprint

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Our study sample is a superconducting bi-dimensional octagon with different boundary conditions immersed in a magnetic external field H. The boundary conditions are simulated by considering different values of the deGennes extrapolation length b on different surfaces of the sample. Our investigation was carried out by solving the two-band time dependent Ginzburg-Landau equations (TB-TDGL). We analyzed the superconducting electron density and the magnetization curves as functions of H and temperature T in zero-field cooling and in zero-field-cooling processes for different values of b and size of the sample. We found a strong dependence of the critical fields on b and size of the sample.

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“…With this, there are essentially several approaches for the study of the superconducting phase (superconducting gap), which are grouped in microscopic terms, based on the Bardeen-Cooper-Schieffer (BCS) theory and re-spective expansions as Migdal-Eliasberg or Bogoliubov-DeGenns [27,28], Ab-initio studies based on its atomic (or molecular) structure and band structure [29] and finally through the phenomenological study, mediated by the time dependent Ginzburg-Landau (TDGL) theory command parameter [30]. Recent discoveries in new unconventional superconducting materials have generated a renewed interest in new interesting topological phases [31], such as multi-band effects (multi-condensed) [32,33], mesoscopic superconductivity [34,35], fractional vorticity [36], kinematic vortices [37] and vortex clusters due to repulsive short-range and attractive long-range interaction [38,39]. Thus, the study of multi-band systems has become essential to capture the essential physics in certain materials of interest such as M gB 2 [40,41], which presents multiple gaps in the superconducting excitation spectrum [42][43][44], also in Sr 2 RuO 4 which in its pure state is one of the best candidates to constitute three-band superconducting order parameters [45][46][47].…”

Section: Introductionmentioning

confidence: 99%

Chiriality in a three-band superconducting prism in ZFC and FC processes

Aguirre¹,

Faundez²,

Magalhães³

et al. 2021

Preprint

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In the present work, we will study the superconducting properties of a mesoscopic threedimensional prism with square transversal section under an external magnetic field in both Zero-Field Cooling (ZFC) and Field-Cooling (FC) process. The studied sample is a three-band system (with three condensates ψ1, ψ2, ψ3), in which we take a Josephson type inter-band coupling simulated via γ parameter. We analyze the magnetization, superconducting electronic density and free Gibbs energy considering both processes. As results, we found an interesting tunneling of vortex and antivortex between the bands, and vortex cluster configuration in the sample. This behaviour is due to the non-monotonic interaction between the bands.

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ZFC process in 2+1 and 3+1 multi-band superconductor

Cited by 15 publications

References 21 publications

Phase shifter based on an ultrathin superconducting bilayer with a through-hole for a superconducting device

Phase shifter based on an ultrathin superconducting bilayer with a through-hole for a superconducting device

Vortex state in a superconducting mesoscopic irregular octagon

Chiriality in a three-band superconducting prism in ZFC and FC processes

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