4,118 research outputs found

    The TF Limit for Rapidly Rotating Bose Gases in Anharmonic Traps

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    Starting from the full many body Hamiltonian we derive the leading order energy and density asymptotics for the ground state of a dilute, rotating Bose gas in an anharmonic trap in the ` Thomas Fermi' (TF) limit when the Gross-Pitaevskii coupling parameter and/or the rotation velocity tend to infinity. Although the many-body wave function is expected to have a complicated phase, the leading order contribution to the energy can be computed by minimizing a simple functional of the density alone

    The Ground State Energy of Dilute Bose Gas in Potentials with Positive Scattering Length

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    The leading term of the ground state energy/particle of a dilute gas of bosons with mass mm in the thermodynamic limit is 2π2aρ/m2\pi \hbar^2 a \rho/m when the density of the gas is ρ\rho, the interaction potential is non-negative and the scattering length aa is positive. In this paper, we generalize the upper bound part of this result to any interaction potential with positive scattering length, i.e, a>0a>0 and the lower bound part to some interaction potentials with shallow and/or narrow negative parts.Comment: Latex 28 page

    Stability of Relativistic Matter With Magnetic Fields

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    Stability of matter with Coulomb forces has been proved for non-relativistic dynamics, including arbitrarily large magnetic fields, and for relativistic dynamics without magnetic fields. In both cases stability requires that the fine structure constant alpha be not too large. It was unclear what would happen for both relativistic dynamics and magnetic fields, or even how to formulate the problem clearly. We show that the use of the Dirac operator allows both effects, provided the filled negative energy `sea' is defined properly. The use of the free Dirac operator to define the negative levels leads to catastrophe for any alpha, but the use of the Dirac operator with magnetic field leads to stability.Comment: This is an announcement of the work in cond-mat/9610195 (LaTeX

    Stability and Instability of Relativistic Electrons in Classical Electro magnetic Fields

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    The stability of matter composed of electrons and static nuclei is investigated for a relativistic dynamics for the electrons given by a suitably projected Dirac operator and with Coulomb interactions. In addition there is an arbitrary classical magnetic field of finite energy. Despite the previously known facts that ordinary nonrelativistic matter with magnetic fields, or relativistic matter without magnetic fields is already unstable when the fine structure constant, is too large it is noteworthy that the combination of the two is still stable provided the projection onto the positive energy states of the Dirac operator, which defines the electron, is chosen properly. A good choice is to include the magnetic field in the definition. A bad choice, which always leads to instability, is the usual one in which the positive energy states are defined by the free Dirac operator. Both assertions are proved here.Comment: LaTeX fil

    The Flux-Phase of the Half-Filled Band

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    The conjecture is verified that the optimum, energy minimizing magnetic flux for a half-filled band of electrons hopping on a planar, bipartite graph is π\pi per square plaquette. We require {\it only} that the graph has periodicity in one direction and the result includes the hexagonal lattice (with flux 0 per hexagon) as a special case. The theorem goes beyond previous conjectures in several ways: (1) It does not assume, a-priori, that all plaquettes have the same flux (as in Hofstadter's model); (2) A Hubbard type on-site interaction of any sign, as well as certain longer range interactions, can be included; (3) The conclusion holds for positive temperature as well as the ground state; (4) The results hold in D2D \geq 2 dimensions if there is periodicity in D1D-1 directions (e.g., the cubic lattice has the lowest energy if there is flux π\pi in each square face).Comment: 9 pages, EHL14/Aug/9

    Effect of electronic interactions on the persistent current in one-dimensional disordered rings

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    The persistent current is here studied in one-dimensional disordered rings that contain interacting electrons. We used the density matrix renormalization group algorithms in order to compute the stiffness, a measure that gives the magnitude of the persistent currents as a function of the boundary conditions for different sets of both interaction and disorder characteristics. In contrast to its non-interacting value, an increase in the stiffness parameter was observed for systems at and off half-filling for weak interactions and non-zero disorders. Within the strong interaction limit, the decrease in stiffness depends on the filling and an analytical approach is developed to recover the observed behaviors. This is required in order to understand its mechanisms. Finally, the study of the localization length confirms the enhancement of the persistent current for moderate interactions when disorders are present at half-filling. Our results reveal two different regimes, one for weak and one for strong interactions at and off half-filling.Comment: 16 pages, 21 figures; minor changes (blanks missing, sentences starting with a mathematical symbol

    Ground-state properties of hard-core bosons confined on one-dimensional optical lattices

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    We study the ground-state properties of hard-core bosons trapped by arbitrary confining potentials on one-dimensional optical lattices. A recently developed exact approach based on the Jordan-Wigner transformation is used. We analyze the large distance behavior of the one-particle density matrix, the momentum distribution function, and the lowest natural orbitals. In addition, the low-density limit in the lattice is studied systematically, and the results obtained compared with the ones known for the hard-core boson gas without the lattice.Comment: RevTex file, 14 pages, 22 figures, published versio

    Improved Lieb-Oxford exchange-correlation inequality with gradient correction

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    We prove a Lieb-Oxford-type inequality on the indirect part of the Coulomb energy of a general many-particle quantum state, with a lower constant than the original statement but involving an additional gradient correction. The result is similar to a recent inequality of Benguria, Bley and Loss, except that the correction term is purely local, which is more usual in density functional theory. In an appendix, we discuss the connection between the indirect energy and the classical Jellium energy for constant densities. We show that they differ by an explicit shift due to the long range of the Coulomb potential.Comment: Final version to appear in Physical Review A. Compared to the very first version, this one contains an appendix discussing the link with the Jellium proble

    The Lieb-Liniger Model as a Limit of Dilute Bosons in Three Dimensions

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    We show that the Lieb-Liniger model for one-dimensional bosons with repulsive δ\delta-function interaction can be rigorously derived via a scaling limit from a dilute three-dimensional Bose gas with arbitrary repulsive interaction potential of finite scattering length. For this purpose, we prove bounds on both the eigenvalues and corresponding eigenfunctions of three-dimensional bosons in strongly elongated traps and relate them to the corresponding quantities in the Lieb-Liniger model. In particular, if both the scattering length aa and the radius rr of the cylindrical trap go to zero, the Lieb-Liniger model with coupling constant ga/r2g \sim a/r^2 is derived. Our bounds are uniform in gg in the whole parameter range 0g0\leq g\leq \infty, and apply to the Hamiltonian for three-dimensional bosons in a spectral window of size r2\sim r^{-2} above the ground state energy.Comment: LaTeX2e, 19 page

    Ground State Energy of the Low Density Bose Gas

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    Now that the properties of low temperature Bose gases at low density, ρ\rho, can be examined experimentally it is appropriate to revisit some of the formulas deduced by many authors 4-5 decades ago. One of these is that the leading term in the energy/particle is 2π2ρa/m2\pi \hbar^2 \rho a/m, where aa is the scattering length. Owing to the delicate and peculiar nature of bosonic correlations, four decades of research have failed to establish this plausible formula rigorously. The only known lower bound for the energy was found by Dyson in 1957, but it was 14 times too small. The correct bound is proved here.Comment: 4 pages, Revtex, reference 12 change
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