2,454,826 research outputs found

    Grover Algorithm with zero theoretical failure rate

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    In standard Grover's algorithm for quantum searching, the probability of finding the marked item is not exactly 1. In this Letter we present a modified version of Grover's algorithm that searches a marked state with full successful rate. The modification is done by replacing the phase inversion by two phase rotation through angle ϕ\phi. The rotation angle is given analytically to be ϕ=2arcsin(sinπ(4J+6)sinβ)\phi=2 \arcsin(\sin{\pi\over (4J+6)}\over \sin\beta), where sinβ=1N\sin\beta={1\over \sqrt{N}}, NN the number of items in the database, and JJ an integer equal to or greater than the integer part of (π2β)/(2β)({\pi\over 2}-\beta)/(2\beta). Upon measurement at (J+1)(J+1)-th iteration, the marked state is obtained with certainty.Comment: 5 pages. Accepted for publication in Physical Review

    Regularization of f(T)f(T) gravity theories and local Lorentz transformation

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    We regularized the field equations of f(T)f(T) gravity theories such that the effect of Local Lorentz Transformation (LLT), in the case of spherical symmetry, is removed. A "general tetrad field", with an arbitrary function of radial coordinate preserving spherical symmetry is provided. We split that tetrad field into two matrices; the first represents a LLT, which contains an arbitrary function, the second matrix represents a proper tetrad field which is a solution to the field equations of f(T)f(T) gravitational theory, (which are not invariant under LLT). This "general tetrad field" is then applied to the regularized field equations of f(T)f(T). We show that the effect of the arbitrary function which is involved in the LLT invariably disappears.Comment: 12 page

    Pair condensation of polarized fermions in the BCS-BEC crossover

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    We investigate a two-component Fermi gas with unequal spin populations along the BCS-BEC crossover. By using the extended BCS equations and the concept of off-diagonal-long-range-order we derive a formula for the condensate number of Cooper pairs as a function of energy gap, average chemical potential, imbalance chemical potential and temperature. Then we study the zero-temperature condensate fraction of Cooper pairs by varying interaction strength and polarization, finding a depletion of the condensate fraction by increasing the population imbalance. We also consider explicitly the presence of an external harmonic confinement and we study, within the local-density approximation, the phase separation between superfluid and normal phase regions of the polarized fermionic cloud. In particular, we calculate both condensate density profiles and total density profiles from the inner superfluid core to the normal region passing for the interface, where a finite jump in the density is a clear manifestation of this phase-separated regime. Finally, we compare our theoretical results with the available experimental data on the condensate fraction of polarized 6Li atoms [Science 311, 492 (2006)]. These experimental data are in reasonable agreement with our predictions in a suitable range of polarizations, but only in the BCS side of the crossover up to unitarity.Comment: 13 pages, 3 figures, improved version, added a section on the interpretation of the results, to be published in J. Phys.

    On the Regularization of Kerr-NUT spacetime: I

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    Within the framework of teleparallel equivalent of general relativity (TEGR) theory, calculation of the total energy and momentum of Kerr-NUT spacetimes have been employed using two methods of the gravitational energy-momentum, which is coordinate independent, and the Riemannian connection 1-form, Γ~αβ{\widetilde{\Gamma}_\alpha}^\beta. It has been shown that the two methods give the same an unacceptable result, i.e., divergent value. Therefore, a local Lorentz transformation that plays a role of a regularizing tool, which subtracts the inertial effects without distorting the true gravitational contribution, has been suggested. This transformation keeps the resulting spacetime to be a solution of the equations of motion of TEGR.Comment: 10 pages, Latex (Will appear in Prog. Theor. Phys.
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