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Superconductivity in doped planar Dirac insulators: A renormalization group study

Superconductivity 2025-06-26 v2 Mesoscale and Nanoscale Physics Materials Science Strongly Correlated Electrons High Energy Physics - Theory

Abstract

From a leading-order unbiased renormalization group analysis we here showcase the emergence of superconductivity (including the topological ones) from purely repulsive electron-electron interactions in two-dimensional doped Dirac insulators, featuring a Fermi surface. In the absence of chemical doping, such systems describe quantum anomalous or spin Hall and normal insulators. Otherwise a simply connected Fermi surface becomes annular deep inside the topological regime. By considering all symmetry allowed repulsive local four-fermion interactions, we show that the nature of the resulting superconducting states at low temperature follows certain Clifford algebraic selection rules, irrespective of the underlying Fermi surface topology. Within the framework of a microscopic Hubbard model, on-site repulsion among fermions with opposite orbitals (spin projections) typically favors topological pp-wave (conventional ss-wave) pairing. Theoretically predicted superconductivity can in principle be observed in experiments once the promising candidate materials for quantum anomalous and spin Hall insulators are doped to foster Fermi surfaces.

Keywords

Cite

@article{arxiv.2502.20394,
  title  = {Superconductivity in doped planar Dirac insulators: A renormalization group study},
  author = {Sk Asrap Murshed and Sanjib Kumar Das and Bitan Roy},
  journal= {arXiv preprint arXiv:2502.20394},
  year   = {2025}
}

Comments

Published version in PRB (Regular Article): 23 Pages, 9 Figures, and 4 Tables

R2 v1 2026-06-28T22:00:40.192Z