55 research outputs found
First-principles studies of water adsorption on graphene: The role of the substrate
We investigate the electronic properties of graphene upon water adsorption
and study the influence of the SiO2 substrate in this context using density
functional calculations. Perfect suspended graphene is rather insensitive to
H2O adsorbates, as doping requires highly oriented H2O clusters. For graphene
on a defective SiO2 substrate, we find a strongly different behavior: H2O
adsorbates can shift the substrate's impurity bands and change their
hybridization with the graphene bands. In this way, H2O can lead to doping of
graphene for much lower adsorbate concentrations than for free hanged graphene.
The effect depends strongly on the microscopic substrate properties.Comment: 4 pages, 3 figure
Switching between Mott-Hubbard and Hund physics in moir\'e quantum simulators
Mott-Hubbard and Hund electron correlations have been realized thus far in
separate classes of materials. Here, we show that a single moir\'e homobilayer
encompasses both kinds of physics in a controllable manner. We develop a
microscopic multiband model that we solve by dynamical mean-field theory to
nonperturbatively address the local many-body correlations. We demonstrate how
tuning with twist angle, dielectric screening, and hole density allows us to
switch between Mott-Hubbard and Hund correlated states in a twisted WSe
bilayer. The underlying mechanism is based on controlling
Coulomb-interaction-driven orbital polarization and the energetics of
concomitant local singlet and triplet spin configurations. From a comparison to
recent experimental transport data, we find signatures of a filling-controlled
transition from a triplet charge-transfer insulator to a Hund-Mott metal. Our
finding establishes twisted transition metal dichalcogenides as a tunable
platform for exotic phases of quantum matter emerging from large local spin
moments
Electronic excitation spectra of the five-orbital Anderson impurity model: From the atomic limit to itinerant atomic magnetism
We study the competition of Coulomb interaction and hybridization effects in the five-orbital Anderson impurity model by means of continuous time quantum Monte Carlo, exact diagonalization, and Hartree-Fock calculations. The dependence of the electronic excitation spectra and thermodynamic ground-state properties on the hybridization strength and the form of the Coulomb interaction is systematically investigated for impurity occupation number N≈6. With increasing hybridization strength, a Kondo resonance emerges, broadens and merges with some of the upper and lower Hubbard peaks. Concomitantly, there is an increase of charge fluctuations at the impurity site. In contrast to the single-orbital model, some atomic multiplet peaks and exchange split satellites persist despite strong charge fluctuations. We find that Hund's coupling leads to a state that may be characterized as an itinerant single atom magnet. As the filling is increased, the magnetic moment decreases, but the spin freezing phenomenon persists up to N≈8. When the hybridization is weak, the positions of atomic ionization peaks are rather sensitive to shifts of the impurity on-site energies. This allows to distinguish atomic ionization peaks from quasiparticle peaks or satellites in the electronic excitation spectra. On the methodological side we show that a comparison between the spectra obtained from Monte Carlo and exact diagonalization calculations is possible if the charge fluctuations are properly matched
Electronic Structures and Optical Properties of Partially and Fully Fluorinated Graphene
In this letter we study the electronic structures and optical properties of
partially and fully fluorinated graphene by a combination of abinitio G0W0
calculations and large-scale multi-orbital tight-binding simulations. We find
that for partially fluorinated graphene, the appearance of paired fluorine
atoms is more favorable than unpaired atoms. We also show that different types
of structural disorder, such as carbon vacancies, fluorine vacancies, fluorine
vacancy-clusters and fluorine armchair- and zigzag-clusters, will introduce
different types of midgap states and extra excitations within the optical gap.
Furthermore we argue that the local formation of bonds upon fluorination
can be distinguished from other disorder inducing mechanisms which do not
destroy the hybrid orbitals by measuring the polarization rotation of
passing polarized light.Comment: Final version appeared in Phys. Rev. Let
Coulomb-Engineered Heterojunctions and Dynamical Screening in Transition Metal Dichalcogenide Monolayers
The manipulation of two-dimensional materials via their dielectric
environment offers novel opportunities to control electronic as well as optical
properties and allows to imprint nanostructures in a non-invasive way. Here we
asses the potential of monolayer semiconducting transition metal
dichalcogenides (TMDCs) for Coulomb engineering in a material realistic and
quantitative manner. We compare the response of different TMDC materials to
modifications of their dielectric surrounding, analyze effects of dynamic
substrate screening, i.e. frequency dependencies in the dielectric functions,
and discuss inherent length scales of Coulomb-engineered heterojunctions. We
find symmetric and rigid-shift-like quasi-particle band-gap modulations for
both, instantaneous and dynamic substrate screening. From this we derive
short-ranged self energies for an effective multi-scale modeling of Coulomb
engineered heterojunctions composed of an homogeneous monolayer placed on a
spatially structured substrate. For these heterojunctions, we show that band
gap modulations on the length scale of a few lattice constants are possible
rendering external limitations of the substrate structuring more important than
internal effects. We find that all semiconducting TMDCs are similarly well
suited for these external and non-invasive modifications.Comment: 10 pages, 7 figure
Critical role of interlayer dimer correlations in the superconductivity of LaNiO
The recent discovery of superconductivity in LaNiO with
under high pressure opens up a new route to
high- superconductivity. This material realizes a bilayer square
lattice model featuring a strong interlayer hybridization unlike many
unconventional superconductors. A key question in this regard concerns how
electronic correlations driven by the interlayer hybridization affect the
low-energy electronic structure and the concomitant superconductivity. Here, we
demonstrate using a cluster dynamical mean-field theory that the interlayer
electronic correlations (IECs) induce a Lifshitz transition resulting in a
change of Fermi surface topology. By solving an appropriate gap equation, we
further show that the dominant pairing instability (intraorbital
-wave/interorbital -wave) is enhanced by the IECs. The
underlying mechanism is the quenching of a strong ferromagnetic channel,
resulting from the Lifshitz transition driven by the IECs. Our finding
establishes the role of IECs in LaNiO and potentially paves the way
to designing higher-\Tc nickelates
Optically and electrically controllable adatom spin-orbital dynamics in transition metal dichalcogenides
We analyze the interplay of spin-valley coupling, orbital physics and
magnetic anisotropy taking place at single magnetic atoms adsorbed on
semiconducting transition-metal dichalcogenides, MX (M = Mo, W; X = S, Se).
Orbital selection rules turn out to govern the kinetic exchange coupling
between the adatom and charge carriers in the MX and lead to highly
orbitally dependent spin-flip scattering rates, as we illustrate for the
example of transition metal adatoms with configuration. Our ab initio
calculations suggest that configurations are realizable by single Co, Rh,
or Ir adatoms on MoS, which additionally exhibit a sizable magnetic
anisotropy. We find that the interaction of the adatom with carriers in the
MX allows to tune its behavior from a quantum regime with full Kondo
screening to a regime of "Ising spintronics" where its spin-orbital moment acts
as classical bit, which can be erased and written electronically and optically.Comment: 6 pages, 4 figure
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