Interacting type-II semi-Dirac quasiparticles
Abstract
Type-II semi-Dirac fermions in two dimensions have been proposed to describe topologically nontrivial low-energy excitations in titanium/vanadium oxide heterostructures. These quasiparticles appear at the merger of three Dirac cones, resulting in a non-zero Berry phase. We find, by employing Hartree-Fock, renormalization group and Random Phase Approximation (RPA) techniques, that the spectrum is very sensitive to long-range electron-electron interactions and can undergo a profound transformation. Our results indicate that at the topological phase boundary, long-range correlations stabilize a hybrid electronic phase displaying both Dirac and type-II semi-Dirac qualities, with physical characteristics exhibiting continuously varying critical exponents as a function of the Fermi energy; for example Landau levels in a magnetic field vary with the energy scale: . The quasiparticle spectrum evolves, driven by interactions, from anisotropic Dirac dispersion at the lowest energies, towards the characteristic type-II semi-Dirac boomerang shape as the energy increases. The corresponding density of states concomitantly varies between linear and power one third (). The crossover scale is controlled by the interaction strength and the specifics of the effective interacting Hamiltonian.
Cite
@article{arxiv.2601.21098,
title = {Interacting type-II semi-Dirac quasiparticles},
author = {Mohamed M. Elsayed and Taras I. Lakoba and Valeri N. Kotov},
journal= {arXiv preprint arXiv:2601.21098},
year = {2026}
}
Comments
11 pages, 6 figures