42,292 research outputs found
Non-unitary representations of the SU(2) algebra in the Dirac equation with a Coulomb potential
A novel realization of the classical SU(2) algebra is introduced for the
Dirac relativistic hydrogen atom defining a set of operators that, besides,
allow the factorization of the problem. An extra phase is needed as a new
variable in order to define the algebra. We take advantage of the operators to
solve the Dirac equation using algebraic methods. To acomplish this, a similar
path to the one used in the angular momentum case is employed; hence, the
radial eigenfuntions calculated comprise non unitary representations of the
algebra. One of the interesting properties of such non unitary representations
is that they are not labeled by integer nor by half-integer numbers as happens
in the usual angular momentum representation.Comment: 20 pages 1 eps figure in a single zipped file, submitted to J. Math.
Phy
Quantum transport through single and multilayer icosahedral fullerenes
We use a tight-binding Hamiltonian and Green functions methods to calculate
the quantum transmission through single-wall fullerenes and bilayered and
trilayered onions of icosahedral symmetry attached to metallic leads. The
electronic structure of the onion-like fullerenes takes into account the
curvature and finite size of the fullerenes layers as well as the strength of
the intershell interactions depending on to the number of interacting atom
pairs belonging to adjacent shells. Misalignment of the symmetry axes of the
concentric icosahedral shells produces breaking of the level degeneracies of
the individual shells, giving rise some narrow quasi-continuum bands instead of
the localized discrete peaks of the individual fullerenes. As a result, the
transmission function for non symmetrical onions are rapidly varying functions
of the Fermi energy. Furthermore, we found that most of the features of the
transmission through the onions are due to the electronic structure of the
outer shell with additional Fano-like antiresonances arising from coupling with
or between the inner shells.Comment: 16 pages, 5 figur
The single-electron transport in a three-ion magnetic molecule modulated by a transverse field
We study single-electron transport in a three-ion molecule with strong
uniaxial anisotropy and in the presence of a transverse magnetic field. Two
magnetic ions are connected to each other through a third, nonmagnetic ion. The
magnetic ions are coupled to ideal metallic leads and a back gate voltage is
applied to the molecule, forming a field-effect transistor. The microscopic
Hamiltonian describing this system includes inter-ion hopping, on-site
repulsions, and magnetic anisotropies. For a range of values of the parameters
of the Hamiltonian, we obtain an energy spectrum similar to that of
single-molecule magnets in the giant-spin approximation where the two states
with maximum spin projection along the uniaxial anisotropy axis are well
separated from other states. In addition, upon applying an external in-plane
magnetic field, the energy gap between the ground and first excited states of
the molecule oscillates, going to zero at certain special values of the field,
in analogy to the diabolical points resulting from Berry phase interference in
the giant spin model. Thus, our microscopic model provides the same
phenomenological behavior expected from the giant spin model of a
single-molecule magnet but with direct access to the internal structure of the
molecule, thus making it more appropriate for realistic electronic transport
studies. To illustrate this point, the nonlinear electronic transport in the
sequential tunneling regime is evaluated for values of the field near these
degeneracy points. We show that the existence of these points has a clear
signature in the I-V characteristics of the molecule, most notably the
modulation of excitation lines in the differential conductance.Comment: 10 pages, 13 figure
Simple Non-Markovian Microscopic Models for the Depolarizing Channel of a Single Qubit
The archetypal one-qubit noisy channels ---depolarizing, phase-damping and
amplitude-damping channels--- describe both Markovian and non-Markovian
evolution. Simple microscopic models for the depolarizing channel, both
classical and quantum, are considered. Microscopic models which describe phase
damping and amplitude damping channels are briefly reviewed.Comment: 13 pages, 2 figures. Title corrected. Paper rewritten. Added
references. Some typos and errors corrected. Author adde
Evaluating the Impact of Community-Based Health Interventions: Evidence from Brazil's Family Health Program
This paper analyzes the direct and indirect impacts of Brazil's Family Health Program. We estimate the effects of the program on mortality and on household behavior related to child labor and schooling, employment of adults, and fertility. We find consistent effects of the program on reductions in mortality throughout the age distribution, but mainly at earlier ages. Municipalities in the poorest regions of the country benefit particularly from the program. For these regions, implementation of the program is also robustly associated with increased labor supply of adults, reduced fertility, and increased schooling. Evidence suggests that the Family Health Program is a highly cost-effective tool for improving health in poor areas.family health program, mortality, household behavior, impact evaluation, Brazil
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