Quantum oscillations reveal a multitone Fermi surface in rhombohedral tetralayer graphene that persists through the superconducting regime and is incompatible with a simply-connected quarter metal.
Geometrical effects in orbital magnetic susceptibility
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abstract
Within the wave-packet semiclassical approach, the Bloch electron energy is derived to second order in the magnetic field and classified into gauge-invariant terms with clear physical meaning, yielding a fresh understanding of the complex behavior of orbital magnetism. The Berry curvature and quantum metric of the Bloch states give rise to a geometrical magnetic susceptibility, which can be dominant when bands are filled up to a small energy gap. There is also an energy polarization term, which can compete with the Peierls-Landau and Pauli magnetism on a Fermi surface. All these, and an additional Langevin susceptibility, can be calculated from each single band, leaving the Van Vleck susceptibility as the only term truly from interband coupling.
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cond-mat.supr-con 1years
2026 1verdicts
UNVERDICTED 1representative citing papers
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Fermiology and the Candidate Chiral Superconductor in Rhombohedral Tetralayer Graphene
Quantum oscillations reveal a multitone Fermi surface in rhombohedral tetralayer graphene that persists through the superconducting regime and is incompatible with a simply-connected quarter metal.