4,900 research outputs found

    Electron-hydrogen scattering in Faddeev-Merkuriev integral equation approach

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    Electron-hydrogen scattering is studied in the Faddeev-Merkuriev integral equation approach. The equations are solved by using the Coulomb-Sturmian separable expansion technique. We present SS- and PP-wave scattering and reactions cross sections up to the H(n=4)H(n=4) threshold.Comment: 2 eps figure

    Faddeev-Merkuriev equations for resonances in three-body Coulombic systems

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    We reconsider the homogeneous Faddeev-Merkuriev integral equations for three-body Coulombic systems with attractive Coulomb interactions and point out that the resonant solutions are contaminated with spurious resonances. The spurious solutions are related to the splitting of the attractive Coulomb potential into short- and long-range parts, which is inherent in the approach, but arbitrary to some extent. By varying the parameters of the splitting the spurious solutions can easily be ruled out. We solve the integral equations by using the Coulomb-Sturmian separable expansion approach. This solution method provides an exact description of the threshold phenomena. We have found several new S-wave resonances in the e- e+ e- system in the vicinity of thresholds.Comment: LaTeX with elsart.sty 13 pages, 5 figure

    Observation of Heteronuclear Feshbach Molecules from a 85^{85}Rb - 87^{87}Rb gas

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    We report on the observation of ultracold heteronuclear Feshbach molecules. Starting with a 87^{87}Rb BEC and a cold atomic gas of 85^{85}Rb, we utilize previously unobserved interspecies Feshbach resonances to create up to 25,000 molecules. Even though the 85^{85}Rb gas is non-degenerate we observe a large molecular conversion efficiency due to the presence of a quantum degenerate 87^{87}Rb gas; this represents a key feature of our system. We compare the molecule creation at two different Feshbach resonances with different magnetic-field widths. The two Feshbach resonances are located at 265.44±0.15265.44\pm0.15 G and 372.4±1.3372.4\pm1.3 G. We also directly measure the small binding energy of the molecules through resonant magnetic-field association.Comment: v2 - minor change

    Series of broad resonances in atomic three-body systems

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    We re-examine the series of resonances found earlier in atomic three-body systems by solving the Faddeev-Merkuriev integral equations. These resonances are rather broad and line-up at each threshold with gradually increasing gaps, the same way for all thresholds and irrespective of the spatial symmetry. We relate these resonances to the Gailitis mechanism, which is a consequence of the polarization potential.Comment: 14 pages, 7 figures. arXiv admin note: text overlap with arXiv:0810.303

    Resonant-state solution of the Faddeev-Merkuriev integral equations for three-body systems with Coulomb potentials

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    A novel method for calculating resonances in three-body Coulombic systems is proposed. The Faddeev-Merkuriev integral equations are solved by applying the Coulomb-Sturmian separable expansion method. The e−e+e−e^- e^+ e^- S-state resonances up to n=5n=5 threshold are calculated.Comment: 6 pages, 2 ps figure
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