The content explores a mechanism to produce superconductivity through strong purely repulsive interactions, without using pairing instability in Fermi-liquids. The resulting superconductors, referred to as topological chiral superconductors, break both time-reversal and reflection symmetries in the orbital motion of electrons, and exhibit non-trivial topological order.
The key insights are:
Topological chiral superconductivity is more likely to emerge near or between fully spin-valley polarized metallic phases (quarter Fermi-liquids) and Wigner crystal phases, as all these phases are driven by strong repulsive interactions.
Unlike conventional BCS superconductors in fully spin-valley polarized metals, these topological chiral superconductors are only partially spin-valley polarized, with the ratios of electron densities associated with different spin-valley quantum numbers quantized as simple rational numbers.
Many of these topological chiral superconductors exhibit charge-4 or higher condensation, and break time-reversal and space reflection symmetry, in addition to carrying gapless chiral edge modes.
One of the topological chiral superconductors (K2a) is in the same phase as the "spin"-triplet p+ip BCS superconductor, while others are in different phases than any BCS superconductors.
The same mechanism can also be used to produce anyon superconductivity between fractional anomalous quantum Hall states in the presence of a periodic potential.
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by Minho Kim, A... a las arxiv.org 10-03-2024
https://arxiv.org/pdf/2409.18067.pdfConsultas más profundas