66,423 research outputs found

    The Effect of Spatial Curvature on the Classical and Quantum Strings

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    We study the effects of the spatial curvature on the classical and quantum string dynamics. We find the general solution of the circular string motion in static Robertson-Walker spacetimes with closed or open sections. This is given closely and completely in terms of elliptic functions. The physical properties, string length, energy and pressure are computed and analyzed. We find the {\it back-reaction} effect of these strings on the spacetime: the self-consistent solution to the Einstein equations is a spatially closed (K>0)(K>0) spacetime with a selected value of the curvature index KK (the scale f* is normalized to unity). No self-consistent solutions with K0K\leq 0 exist. We semi-classically quantize the circular strings and find the mass mm in each case. For K>0,K>0, the very massive strings, oscillating on the full hypersphere, have m2Kn2    (nN0)m^2\sim K n^2\;\;(n\in N_0) {\it independent} of α\alpha' and the level spacing {\it grows} with n,n, while the strings oscillating on one hemisphere (without crossing the equator) have m2αnm^2\alpha'\sim n and a {\it finite} number of states N1/(Kα).N\sim 1/(K\alpha'). For K<0,K<0, there are infinitely many string states with masses mlogmn,m\log m\sim n, that is, the level spacing grows {\it slower} than n.n. The stationary string solutions as well as the generic string fluctuations around the center of mass are also found and analyzed in closed form.Comment: 30 pages Latex + three tables and five figures (not included

    Practical implementation of mutually unbiased bases using quantum circuits

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    The number of measurements necessary to perform the quantum state reconstruction of a system of qubits grows exponentially with the number of constituents, creating a major obstacle for the design of scalable tomographic schemes. We work out a simple and efficient method based on cyclic generation of mutually unbiased bases. The basic generator requires only Hadamard and controlled-phase gates, which are available in most practical realizations of these systems. We show how complete sets of mutually unbiased bases with different entanglement structures can be realized for three and four qubits. We also analyze the quantum circuits implementing the various entanglement classes.Comment: 5 pages, 2 color figures. Comments welcome
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