Abstract
The superconducting s-wave state in Weyl semimetals in a strong strain-induced pseudomagnetic field is investigated in a model with local four-fermion interaction. It is found that only the inter-node pairing is possible in the lowest pseudo-Landau level approximation. Unlike the case of the lowest Landau level in a conventional magnetic field, the corresponding gap equation has only a trivial solution. Nevertheless, superconductivity can be induced via the proximity effect with a usual s-wave spin-singlet superconductor. Since a pseudomagnetic field is present necessarily at the surface of a Weyl semimetal, the proximity effect is strongly affected by the pseudomagnetic field. The analysis of such an effect showed that while no gap is opened in the spectrum, the degeneracy of energy levels is lifted. The unique character of the proximity effect in Weyl semimetals can be probed via the density of states, the spectral function, and the tunneling current. The density of states does not vanish at small energies and scales linearly with the pseudomagnetic field strength. This scaling is manifested also in the tunneling current.
Highlights
The interplay of superconductivity and magnetic fields is a nontrivial problem with a rich history as well as high fundamental and applied impact
While we found that a strong pseudomagnetic field does not support an intrinsic swave superconducting state, the proximity effect with a usual s-wave superconductor can still induce superconductivity in Weyl semimetals
As we argue in this paper, the proximity effect in Weyl semimetals is unusual since it is affected strongly by a pseudomagnetic field
Summary
The interplay of superconductivity and magnetic fields is a nontrivial problem with a rich history as well as high fundamental and applied impact. We investigate a different possibility to realize an unconventional superconducting state in Weyl semimetals It relies on strong pseudomagnetic fields generated by mechanical strains [33,34,35] Since pseudoelectromagnetic fields have a completely different physical origin compared to usual electromagnetic fields, they do not induce diamagnetic currents that can back-react and destroy the superconducting state This suggests that the Meissner effect should be absent for pseudomagnetic fields and implies that these fields may naively enhance and promote the superconductivity in Weyl semimetals.
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