Evolution of pair correlation symmetries and supercurrent reversal in tilted Weyl semimetals

Alidoust, Mohammad; Halterman, Klaus

doi:10.1103/physrevb.101.035120

Cited by 32 publications

(21 citation statements)

References 94 publications

Supporting

Mentioning

Contrasting

Order By: Relevance

“…Further details of the numerical algorithm employed for studying the supercurrent can be found in Refs. [67][68][69][70]. This method agrees well with Gorkov's Green's function approach and also can provide access to the quasiclassical regime where the Fermi energy is the largest energy in the system [67][68][69][70][71][72][73].…”

supporting

confidence: 71%

“…[67][68][69][70]. This method agrees well with Gorkov's Green's function approach and also can provide access to the quasiclassical regime where the Fermi energy is the largest energy in the system [67][68][69][70][71][72][73]. To simplify the calculations, we have ignored the inverse proximity effects and considered a situation where the roughness of the interfaces plays a relatively weak role, which is the experimentally relevant regime [1,2].…”

supporting

confidence: 55%

“…The behavior of the supercurrent is governed by the complicated interplay of lattice symmetry and the actual pairing mechanism. If unconventional odd-parity p-wave and f -wave pairing mechanisms are involved, the combination of an appropriate Zeeman field in a Josephson junction with different p-wave ( f -wave) orientations in superconducting leads (or s-wave electrodes) can result in a self-biased current [67][68][69][70][71][72][73]. The cases considered above do not exhaust all theoretical possibilities for introducing superconductivity in the BLG system, but they serve as illustrative examples for what can take place, while further computations should be guided by experimental systems.…”

mentioning

confidence: 99%

See 2 more Smart Citations

Josephson effect in graphene bilayers with adjustable relative displacement

Alidoust

Jauho

Akola

2020

Phys. Rev. Research

Self Cite

View full text Add to dashboard Cite

The Josephson current is investigated in a superconducting graphene bilayer where pristine graphene sheets can make in-plane or out-of-plane displacements with respect to each other. The superconductivity can be of an intrinsic nature, or due to a proximity effect. The results demonstrate that the supercurrent responds qualitatively differently to relative displacement if the superconductivity is due to either intralayer or interlayer spin-singlet electron-electron pairing, thus providing a tool to distinguish between the two mechanisms. Specifically, both the AA and AB stacking orders are studied with antiferromagnetic spin alignment. For the AA stacking order with intralayer and on-site pairing no current reversal is found. In contrast, the supercurrent may switch its direction as a function of the in-plane displacement and out-of-plane interlayer coupling for the cases of AA ordering with interlayer pairing and AB ordering with either intralayer or interlayer pairing. In addition to sign reversal, the Josephson signal displays many characteristic fingerprints which derive directly from the pairing mechanism. Thus, measurements of the Josephson current as a function of the graphene bilayer displacement open up the means to achieve deeper insights into the superconducting pairing mechanism.

show abstract

supporting

confidence: 71%

supporting

confidence: 55%

mentioning

confidence: 99%

See 1 more Smart Citation

Josephson effect in graphene bilayers with adjustable relative displacement

Alidoust

Jauho

Akola

2020

Phys. Rev. Research

Self Cite

View full text Add to dashboard Cite

show abstract

“…The ABS can be experimentally investigated by virtue of the CPR I(φ), which just in turn confirms the presence of the CMMs and their contributions to supercurrent. According to equation (10), we calculate I(φ) by using the Andreev bound energies E(φ) of figures 2(a)-(c), which are shown in figure 3(a) for the three magnetic configurations. The sinusoidal shape with periodicity 2π is no more exhibited for each magnetic configuration.…”

Section: Controllable Cmms By the Misorientation Anglementioning

confidence: 99%

“…The anomalous Josephson effect has emerged in the Josephson junctions based on such materials as black phosphorus and tilted Weyl semimetals [5][6][7][8][9]. The φ 0 state can be leveraged to determine the Majorana fermions, type of spin-orbit coupling, order of spin-orbit coupling (linear or cubic), and pairing symmetries [10][11][12].…”

Section: Introductionmentioning

confidence: 99%

Controllable chiral Majorana modes by noncollinear magnetic configuration in a topological Josephson junction

et al. 2022

New J. Phys.

View full text Add to dashboard Cite

Recently, theory and experiment both have confirmed a Majorana zero mode to induce selective equal spin Andreev reflection (SESAR). Herein, we theoretically present controllable chiral Majorana modes (CMMs) by noncollinear magnetic configuration in a Josephson junction on a topological insulator with two ferromagnetic insulators (FIs) sandwiched in between two superconductors (SCs). It is shown that an additional phase shift is induced by the different chirality of the CMMs at the two FI/SC interfaces, whose magnitude is determined by misorientational angle θ, which can be administrated by the Andreev bound surface energies. The angle θ is found to result in the 0-π state transition and Φ0 supercurrent. Particularly, due to the SESAR, the coexistence of fully spin-polarized spin-singlet and -triplet correlations is exhibited with the exclusive fully spin-polarized spin-triplet (singlet) correlation corresponding to the ferromagnetic (F) [antiferromagnetic (AF)] configuration. For the two magnetizations only along y-axis, there exist no additional phase shift and topological supercurrent with fully spin-polarized correlations, especially, the supercurrent in the AF configuration is a lot larger than that in the F one, which is strongly dependent on the exchange field strength and FI length, thus even leading to 100% supercurrent magnetoresistance. The results can be employed to not only identify the topological SCs but also design a perfect topological supercurrent spin valve device.

show abstract

Tunneling Phase Diagrams in Anisotropic Multi‐Weyl Semimetals

et al. 2022

View full text Add to dashboard Cite

Motivated by the exciting prediction of multi‐Weyl topological semimetals stabilized by point group symmetries, tunneling in anisotropic multi‐Weyl semimetals is studied. It is found that distant detectors for different ranges of an anisotropy parameter λ and incident angle θ will measure different numbers of propagating transmitted modes. These findings are presented as phase diagrams that are valid for incoming waves with fixed wavenumber k. Energy is not held fixed for incoming waves but allowed to vary with choice of incident angle and wavenumber k. To gain a deeper understanding of this phenomenon they focus on the simplest case of anisotropic quadratic Weyl‐semimetals and tunneling coefficients are analyzed analytically and numerically to confirm observations extracted from phase diagrams. Results show nonanalytical behavior, which is the hallmark of phase transitions. This serves as motivation to make a formal analogy with phase transitions known from statistical mechanics. Specifically, they argued that the long distance limit in the tunneling problem mimics the thermodynamic limit in statistical mechanics. A direct formal connection is found to the recently developed formalism of dynamical phase transitions. They propose that usage of this analogy with dynamical phase transitions can be fruitful in classifying transport properties of exotic semimetals.

show abstract

Evolution of pair correlation symmetries and supercurrent reversal in tilted Weyl semimetals

Cited by 32 publications

References 94 publications

Josephson effect in graphene bilayers with adjustable relative displacement

Josephson effect in graphene bilayers with adjustable relative displacement

Controllable chiral Majorana modes by noncollinear magnetic configuration in a topological Josephson junction

Tunneling Phase Diagrams in Anisotropic Multi‐Weyl Semimetals

Contact Info

Product

Resources

About