1,168 research outputs found
Valley Hall effect in disordered monolayer MoS2 from first principles
Electrons in certain two-dimensional crystals possess a pseudospin degree of
freedom associated with the existence of two inequivalent valleys in the
Brillouin zone. If, as in monolayer MoS2, inversion symmetry is broken and
time-reversal symmetry is present, equal and opposite amounts of k-space Berry
curvature accumulate in each of the two valleys. This is conveniently
quantified by the integral of the Berry curvature over a single valley - the
valley Hall conductivity. We generalize this definition to include
contributions from disorder described with the supercell approach, by mapping
("unfolding") the Berry curvature from the folded Brillouin zone of the
disordered supercell onto the normal Brillouin zone of the pristine crystal,
and then averaging over several realizations of disorder. We use this scheme to
study from first-principles the effect of sulfur vacancies on the valley Hall
conductivity of monolayer MoS2. In dirty samples the intrinsic valley Hall
conductivity receives gating-dependent corrections that are only weakly
dependent on the impurity concentration, consistent with side-jump scattering
and the unfolded Berry curvature can be interpreted as a k-space resolved
side-jump. At low impurity concentrations skew scattering dominates, leading to
a divergent valley Hall conductivity in the clean limit. The implications for
the recently-observed photoinduced anomalous Hall effect are discussed.Comment: 13 page
Gyrotropic magnetic effect and the magnetic moment on the Fermi surface
The current density induced in a clean metal by a
slowly-varying magnetic field is formulated as the low-frequency
limit of natural optical activity, or natural gyrotropy. Working with a
multiband Pauli Hamiltonian, we obtain from the Kubo formula a simple
expression for in terms of the
intrinsic magnetic moment (orbital plus spin) of the Bloch electrons on the
Fermi surface. An alternate semiclassical derivation provides an intuitive
picture of the effect, and takes into account the influence of scattering
processes in dirty metals. This "gyrotropic magnetic effect" is fundamentally
different from the chiral magnetic effect driven by the chiral anomaly and
governed by the Berry curvature on the Fermi surface, and the two effects are
compared for a minimal model of a Weyl semimetal. Like the Berry curvature, the
intrinsic magnetic moment should be regarded as a basic ingredient in the
Fermi-liquid description of transport in broken-symmetry metals.Comment: The Supplemental Material can be found at
http://cmt.berkeley.edu/suppl/zhong-arxiv15-suppl.pd
Surface theorem for the Chern-Simons axion coupling
The Chern-Simons axion coupling of a bulk insulator is only defined modulo a
quantum of e^2/h. The quantized part of the coupling is uniquely defined for a
bounded insulating sample, but it depends on the specific surface termination.
Working in a slab geometry and representing the valence bands in terms of
hybrid Wannier functions, we show how to determine that quantized part from the
excess Chern number of the hybrid Wannier sheets located near the surface of
the slab. The procedure is illustrated for a tight-binding model consisting of
coupled quantum anomalous Hall layers. By slowly modulating the model
parameters, it is possible to transfer one unit of Chern number from the bottom
to the top surface over the course of a cyclic evolution of the bulk
Hamiltonian. When the evolution of the surface Hamiltonian is also cyclic, the
Chern pumping is obstructed by chiral touchings between valence and conduction
surface bands.Comment: 15 page
Orbital magnetoelectric coupling at finite electric field
We extend the band theory of linear orbital magnetoelectric coupling to treat
crystals under finite electric fields. Previous work established that the
orbital magnetoelectric response of a generic insulator at zero field comprises
three contributions that were denoted as local circulation, itinerant
circulation, and Chern-Simons. We find that the expression for each of them is
modified by the presence of a dc electric field. Remarkably, the sum of the
three correction terms vanishes, so that the total coupling is still given by
the same formula as at zero field. This conclusion is confirmed by numerical
tests on a tight-binding model, for which we calculate the field-induced change
in the linear magnetoelectric coefficient.Comment: 4 pages, 2 figure
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