We construct a generalized transfer matrix corresponding to noninteracting tight-binding lattice models, which can subsequently be used to compute the bulk bands as well as the edge states. Crucially, our formalism works even in cases where the hopping matrix is non-invertible. Following Hatsugai [PRL 71, 3697 (1993)], we explicitly construct the energy Riemann surfaces associated with the band structure for a specific class of systems which includes systems like Chern insulator, Dirac semimetal and graphene. The edge states can then be interpreted as non-contractible loops, with the winding number equal to the bulk Chern number. For these systems, the transfer matrix is symplectic, and hence we also describe the windings associated with the edge states on Sp(2, R) and interpret the corresponding winding number as a Maslov index.
Topological phases of Hermitian systems are known to exhibit intriguing properties such as the presence of robust boundary states and the famed bulk-boundary correspondence. These features can change drastically for their non-Hermitian generalizations, as exemplified by a general breakdown of bulk-boundary correspondence and a localization of all states at the boundary, termed the non-Hermitian skin effect. In this paper, we present a completely analytical unifying framework for studying these systems using generalized transfer matrices -a real-space approach suitable for systems with periodic as well as open boundary conditions. We show that various qualitative properties of these systems can be easily deduced from the transfer matrix. For instance, the connection between the breakdown of the conventional bulk-boundary correspondence and the existence of a non-Hermitian skin effect, previously observed numerically, is traced back to the transfer matrix having a determinant not equal to unity. The vanishing of this determinant signals real-space exceptional points, whose order scales with the system size. We also derive previously proposed topological invariants such as the biorthogonal polarization and the Chern number computed on a complexified Brillouin zone. Finally, we define an invariant for and thereby clarify the meaning of topologically protected boundary modes for non-Hermitian systems. arXiv:1812.02186v3 [cond-mat.mes-hall]
We propose a classical action for the motion of massless Weyl fermions in a background gauge field in (2N + 1) + 1 spacetime dimensions. We use this action to derive the collisionless Boltzmann equation for a gas of such particles, and show how classical versions of the gauge and Abelian chiral anomalies arise from the Chern character of the non-Abelian Berry connection that parallel transports the spin degree of freedom in momentum space.
The Wigner little group for massless particles is isomorphic to the Euclidean group SE(2).Applied to momentum eigenstates, or to infinite plane waves, the Euclidean "Wigner translations" act as the identity. We show that when applied to finite wavepackets the translation generators move the packet trajectory parallel to itself through a distance proportional to the particle's helicity.We relate this effect to the spin Hall effect of light and to the Lorentz-frame dependence of the position of a massless spinning particle.
Frustrated magnetic systems exhibit many fascinating phases. Prime among them
are quantum spin liquids, where the magnetic moments do not order even at zero
temperature. A subclass of quantum spin liquids called Kitaev spin liquids are
particularly interesting, because they are exactly solvable, can be realized in
certain materials, and show a large variety of gapless and gapped phases. Here,
we show that non-symmorphic symmetries can enrich spin liquid phases, such that
the low-energy spinon degrees of freedom form three-dimensional Dirac cones or
nodal chains. In addition, we suggest how such Kitaev spin liquids may be
realized in metal-organic-frameworks.Comment: 17 pages, 11 figure
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