62 research outputs found
Optimized perturbation method for the propagation in the anharmonic oscillator potential
The application of the optimized expansion for the quantum-mechanical
propagation in the anharmonic potential is discussed for real and
imaginary time. The first order results in the imaginary time formalism provide
approximations to the free energy and particle density which agree well with
the exact results in the whole range of temperatures.Comment: 13 pages, plain LATEX, 3 compressed and uuencoded Postscript figures,
submitted to Phys.Lett.
Optimized Perturbation Methods for the Free Energy of the Anharmonic Oscillator
Two possibile applications of the optimized expansion for the free energy of
the quantum-mechanical anharmonic oscillator are discussed. The first method is
for the finite temperature effective potential; the second one, for the
classical effective potential. The results of both methods show a quick
convergence and agree well with the exact free energy in the whole range of
temperatures. Postscript figures are available under request to AO email
[email protected]: 8 pages, preprin
Goldstone Bosons in the Gaussian Approximation
The O(N) symmetric scalar quantum field theory with \lambda\Phi^4 interaction
is discussed in the Gaussian approximation. It is shown that the Goldstone
theorem is fulfilled for arbitrary N.Comment: 7 pages, Late
The Finite Temperature Effective Potential for Local Composite Operators
The method of the effective action for the composite operators
and is applied to the termodynamics of the scalar quantum field
with interaction. An expansion of the finite temperature
effective potential in powers of provides successive approximations to
the free energy with an effective mass and an effective coupling determined by
the gap equations. The numerical results are studied in the space-time of one
dimension, when the theory is equivalent to the quantum mechanics of an
anharmonic oscillator. The approximations to the free energy show quick
convergence to the exact result.Comment: 10 pages, plain Latex, 2 figure
The Effective Action for Local Composite Operators and
The generating functionals for the local composite operators, and
, are used to study excitations in the scalar quantum field theory
with interaction. The effective action for the composite
operators is obtained as a series in the Planck constant , and the two-
and four-particle propagators are derived. The numerical results are studied in
the space-time of one dimension, when the theory is equivalent to the quantum
mechanics of an anharmonic oscillator. The effective potential and the poles of
the composite propagators are obtained as series in , with effective
mass and coupling determined by non-perturbative gap equations. This provides a
systematic approximation method for the ground state energy, and for the second
and fourth excitations. The results show quick convergence to the exact values,
better than that obtained without including the operator .Comment: 15 pages, plain Latex, 1 compressed and uuencoded Postscript figur
Two-electron resonances in quasi-one dimensional quantum dots with Gaussian confinement
We consider a quasi one-dimensional quantum dot composed of two Coulombically
interacting electrons confined in a Gaussian trap. Apart from bound states, the
system exhibits resonances that are related to the autoionization process.
Employing the complex-coordinate rotation method, we determine the resonance
widths and energies and discuss their dependence on the longitudinal
confinement potential and the lateral radius of the quantum dot. The stability
properties of the system are discussed.Comment: 12 pages, 7 figure
Two-boson Correlations in Various One-dimensional Traps
A one-dimensional system of two trapped bosons which interact through a
contact potential is studied using the optimized configuration interaction
method. The rapid convergence of the method is demonstrated for trapping
potentials of convex and non-convex shapes. The energy spectra, as well as
natural orbitals and their occupation numbers are determined in function of the
inter-boson interaction strength. Entanglement characteristics are discussed in
dependence on the shape of the confining potential.Comment: 5 pages, 3 figure
Discrete symmetry breaking and restoration at finite temperature in 3D Gross-Neveu model
Dynamical spontaneous breaking of some discrete symmetries including special
parities and time reversal and their restoration at finite temperature T are
researched in 3D Gross-Neveu model by means of Schwinger-Dyson equation in the
real-time thermal field theory in the fermion bubble diagram approximation.
When the momentum cut-off is large enough, the equation of critical
chemical potential and critical temperature will be
-independent and identical to the one obtained by auxialiary scalar
field approach. The dynamical fermion mass m, as the order parameter of
symmetry breaking, has the same behavior as one in 4D NJL-model
when T is less than and near and this shows the second-order phase
transition feature of the symmetry restoration at . It is also proven
that no scalar bound state could exist in this model.Comment: 8 pages, Latex, no figure, Phys. Lett. B., to be publishe
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