105 research outputs found
Semiclassical Approach to Orbital Magnetism of Interacting Diffusive Quantum Systems
We study interaction effects on the orbital magnetism of diffusive mesoscopic
quantum systems. By combining many-body perturbation theory with semiclassical
techniques, we show that the interaction contribution to the ensemble averaged
quantum thermodynamic potential can be reduced to an essentially classical
operator. We compute the magnetic response of disordered rings and dots for
diffusive classical dynamics. Our semiclassical approach reproduces the results
of previous diagrammatic quantum calculations.Comment: 8 pages, revtex, includes 1 postscript fi
Incipient Wigner Localization in Circular Quantum Dots
We study the development of electron-electron correlations in circular
quantum dots as the density is decreased. We consider a wide range of both
electron number, N<=20, and electron gas parameter, r_s<18, using the diffusion
quantum Monte Carlo technique. Features associated with correlation appear to
develop very differently in quantum dots than in bulk. The main reason is that
translational symmetry is necessarily broken in a dot, leading to density
modulation and inhomogeneity. Electron-electron interactions act to enhance
this modulation ultimately leading to localization. This process appears to be
completely smooth and occurs over a wide range of density. Thus there is a
broad regime of ``incipient'' Wigner crystallization in these quantum dots. Our
specific conclusions are: (i) The density develops sharp rings while the pair
density shows both radial and angular inhomogeneity. (ii) The spin of the
ground state is consistent with Hund's (first) rule throughout our entire range
of r_s for all 4<N<20. (iii) The addition energy curve first becomes smoother
as interactions strengthen -- the mesoscopic fluctuations are damped by
correlation -- and then starts to show features characteristic of the classical
addition energy. (iv) Localization effects are stronger for a smaller number of
electrons. (v) Finally, the gap to certain spin excitations becomes small at
the strong interaction (large r_s) side of our regime.Comment: 14 pages, 12 figure
Chaos and Interacting Electrons in Ballistic Quantum Dots
We show that the classical dynamics of independent particles can determine
the quantum properties of interacting electrons in the ballistic regime. This
connection is established using diagrammatic perturbation theory and
semiclassical finite-temperature Green functions. Specifically, the orbital
magnetism is greatly enhanced over the Landau susceptibility by the combined
effects of interactions and finite size. The presence of families of periodic
orbits in regular systems makes their susceptibility parametrically larger than
that of chaotic systems, a difference which emerges from correlation terms.Comment: 4 pages, revtex, includes 3 postscript fig
Far-from-equilibrium noise heating and laser cooling dynamics in radio-frequency Paul traps
We study the stochastic dynamics of a particle in a periodically driven
potential. For atomic ions trapped in radio-frequency Paul traps, noise heating
and laser cooling typically act slowly in comparison with the unperturbed
motion. These stochastic processes can be accounted for in terms of a
probability distribution defined over the action variables, which would
otherwise be conserved within the regular regions of the Hamiltonian phase
space. We present a semiclassical theory of low-saturation laser cooling
applicable from the limit of low-amplitude motion to large-amplitude motion,
accounting fully for the time-dependent and anharmonic trap. We employ our
approach to a detailed study of the stochastic dynamics of a single ion,
drawing general conclusions regarding the nonequilibrium dynamics of
laser-cooled trapped ions. We predict a regime of anharmonic motion in which
laser cooling becomes diffusive (i.e., it is equally likely to cool the ion as
it is to heat it), and can also turn into effective heating. This implies that
a high-energy ion could be easily lost from the trap despite being laser
cooled; however, we find that this loss can be counteracted using a laser
detuning much larger than Doppler detuning.Comment: 23 pages, 7 figure
Marginal topological properties of graphene: a comparison with topological insulators
The electronic structures of graphene systems and topological insulators have
closely-related features, such as quantized Berry phase and zero-energy edge
states. The reason for these analogies is that in both systems there are two
relevant orbital bands, which generate the pseudo-spin degree of freedom, and,
less obviously, there is a correspondence between the valley degree of freedom
in graphene and electron spin in topological insulators. Despite the
similarities, there are also several important distinctions, both for the bulk
topological properties and for their implications for the edge states --
primarily due to the fundamental difference between valley and spin. In view of
their peculiar band structure features, gapped graphene systems should be
properly characterized as marginal topological insulators, distinct from either
the trivial insulators or the true topological insulators.Comment: This manuscript will be published on the Proceedings of the 2010
Nobel Symposium on Graphene and Quantum Matte
Spin Qubits in Multi-Electron Quantum Dots
We study the effect of mesoscopic fluctuations on the magnitude of errors
that can occur in exchange operations on quantum dot spin-qubits. Mid-size
double quantum dots, with an odd number of electrons in the range of a few tens
in each dot, are investigated through the constant interaction model using
realistic parameters. It is found that the constraint of having short pulses
and small errors implies keeping accurate control, at the few percent level, of
several electrode voltages. In practice, the number of independent parameters
per dot that one should tune depends on the configuration and ranges from one
to four.Comment: RevTex, 6 pages, 5 figures. v3: two figures added, more details
provided. Accepted for publication in PR
Orbital Magnetism in Ensembles of Parabolic Potentials
We study the magnetic susceptibility of an ensemble of non-interacting
electrons confined by parabolic potentials and subjected to a perpendicular
magnetic field at finite temperatures. We show that the behavior of the average
susceptibility is qualitatively different from that of billiards. When averaged
over the Fermi energy the susceptibility exhibits a large paramagnetic response
only at certain special field values, corresponding to comensurate classical
frequencies, being negligible elsewhere. We derive approximate analytical
formulae for the susceptibility and compare the results with numerical
calculations.Comment: 4 pages, 4 figures, REVTE
Short-range interactions in a two-electron system: energy levels and magnetic properties
The problem of two electrons in a square billiard interacting via a
finite-range repulsive Yukawa potential and subjected to a constant magnetic
field is considered. We compute the energy spectrum for both singlet and
triplet states, and for all symmetry classes, as a function of the strength and
range of the interaction and of the magnetic field. We show that the
short-range nature of the potential suppresses the formation of ``Wigner
molecule'' states for the ground state, even in the strong interaction limit.
The magnetic susceptibility shows low-temperature paramagnetic peaks
due to exchange induced singlet-triplet oscillations. The position, number and
intensity of these peaks depend on the range and strength of the interaction.
The contribution of the interaction to the susceptibility displays paramagnetic
and diamagnetic phases as a function of .Comment: 12 pages,6 figures; to appear in Phys. Rev.
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