140 research outputs found
Stable Quantum Monte Carlo Simulations for Entanglement Spectra of Interacting Fermions
We show that the two recently proposed methods to compute Renyi entanglement
entropies in the realm of determinant quantum Monte Carlo methods for fermions
are in principle equivalent, but differ in sampling strategies. The analogy
allows to formulate a numerically stable calculation of the entanglement
spectrum at strong coupling. We demonstrate the approach by studying static and
dynamical properties of the entanglement hamiltonian across the interaction
driven quantum phase transition between a topological insulator and quantum
antiferromagnet in the Kane-Mele Hubbard model. The formulation is not limited
to fermion systems and can readily be adapted to world-line based simulations
of bosonic systems.Comment: 8 pages, 5 figure
Emergent Coherent Lattice Behavior in Kondo Nanosystems
How many magnetic moments periodically arranged on a metallic surface are
needed to generate a coherent Kondo lattice behavior? We investigate this
fundamental issue within the particle-hole symmetric Kondo lattice model using
quantum Monte Carlo simulations. Extra magnetic atoms forming closed shells
around the initial impurity induce a fast splitting of the Kondo resonance at
the inner shells which signals the formation of composite heavy-fermion bands.
The onset of the hybridization gap matches well the enhancement of
antiferromagnetic spin correlations in the plane perpendicular to the applied
magnetic field, a genuine feature of the coherent Kondo lattice. In contrast,
the outermost shell remains dominated by a local Kondo physics with spectral
features resembling the single-impurity behavior.Comment: 4+ pages plus supplemental material; published versio
Interplay between the edge-state magnetism and long-range Coulomb interaction in zigzag graphene nanoribbons: quantum Monte Carlo study
We perform projective quantum Monte Carlo simulations of zigzag graphene
nanoribbons within a realistic model with long-range Coulomb interactions.
Increasing the relative strength of nonlocal interactions with respect to the
on-site repulsion does not generate a phase transition but has a number of
nontrivial effects. At the single-particle level we observe a marked
enhancement of the Fermi velocity at the Dirac points. At the two-particle
level, spin- and charge-density-wave fluctuations compete. As a consequence,
the edge magnetic moment is reduced but the edge dispersion relation increases
in the sense that the single-particle gap at momentum
grows. We attribute this to nonlocal charge fluctuations which assist the spin
fluctuations to generate the aforementioned gap. In contrast, the net result of
the interaction-induced renormalization of different energy scales is a
constant spin-wave velocity of the edge modes. However, since the particle-hole
continuum is shifted to higher energies---due to the renormalization of the
Fermi velocity---Landau damping is reduced. As a result, a roughly linear
spin-wave-like mode at the edge spreads out through a larger part of the
Brillouin zone.Comment: 11 pages, 11 figures, comment about doped nanoribbon
Melting of stripe phases and its signature in the single-particle spectral function
Motivated by the recent experimental data [Phys. Rev. B 79, 100502 (2009)]
indicating the existence of a pure stripe charge order over unprecedently wide
temperature range in La_{1.8-x}Eu_{0.2}Sr_xCuO_4, we investigate the
temperature-induced melting of the metallic stripe phase. In spite of taking
into account local dynamic correlations within a real-space dynamical
mean-field theory of the Hubbard model, we observe a mean-field like melting of
the stripe order irrespective of the choice of the next-nearest neighbor
hopping. The temperature dependence of the single-particle spectral function
shows the stripe induced formation of a flat band around the antinodal points
accompanied by the opening a gap in the nodal direction.Comment: 4 pages, 5 figures, minor changes, added Ref. 1
Dynamically generated edge states in topological Kondo insulators
Kondo insulators combine strong electronic correlations with spin orbit
coupling and thereby provide a potential realization of correlated topological
insulators. We present model calculations which allow us to study the onset of
bulk coherence and concomitant topological edge states from the mixed valence
to local moment regimes. Our real-space dynamical mean-field results include
the detailed temperature dependence of the single particle spectral function on
slab geometries as well as the temperature dependence of the topological
invariant. The relevance of our calculations for candidate materials like SmB6
is discussed.Comment: 7 pages, 6 figure
Pinning the order: the nature of quantum criticality in the Hubbard model on honeycomb lattice
In numerical simulations, spontaneously broken symmetry is often detected by
computing two-point correlation functions of the appropriate local order
parameter. This approach, however, computes the square of the local order
parameter, and so when it is {\it small}, very large system sizes at high
precisions are required to obtain reliable results. Alternatively, one can pin
the order by introducing a local symmetry breaking field, and then measure the
induced local order parameter infinitely far from the pinning center. The
method is tested here at length for the Hubbard model on honeycomb lattice,
within the realm of the projective auxiliary field quantum Monte Carlo
algorithm. With our enhanced resolution we find a direct and continuous quantum
phase transition between the semi-metallic and the insulating antiferromagnetic
states with increase of the interaction. The single particle gap in units of
the Hubbard tracks the staggered magnetization. An excellent data collapse
is obtained by finite size scaling, with the values of the critical exponents
in accord with the Gross-Neveu universality class of the transition.Comment: 7 pages, 6 figures, Published versio
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