6,349 research outputs found

    Branching Fractions and CP Asymmetries of the Quasi-Two-Body Decays in Bsβ†’K0(Kβ€Ύ0)KΒ±Ο€βˆ“B_{s} \to K^0(\overline K^0)K^\pm \pi^\mp within PQCD Approach

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    Motivated by the first untagged decay-time-integrated amplitude analysis of Bsβ†’KSKβˆ“Ο€Β±B_s \to K_SK^{\mp}\pi^{\pm} decays performed by LHCb collaboration, where the decay amplitudes are modeled to contain the resonant contributions from intermediate resonances Kβˆ—(892)K^*(892), K0βˆ—(1430)K_0^*(1430) and K2βˆ—(1430)K_2^*(1430), we comprehensively investigate the quasi-two-body Bsβ†’K0/Kβ€Ύ0KΒ±Ο€βˆ“B_{s} \to K^0/\overline{\kern -0.2em K}^0 K^{\pm}\pi^{\mp} decays, and calculate the branching fractions and the time-dependent CPCP asymmetries within the perturbative QCD approach based on the kTk_T factorization. In the quasi-two-body space region the calculated branching fractions with the considered intermediate resonances are in good agreement with the experimental results of LHCb by adopting proper KΟ€K\pi pair wave function, describing the interaction between the kaon and pion in the KΟ€K\pi pair. Furthermore,within the obtained branching fractions of the quasi-two-body decays, we also calculate the branching fractions of corresponding two-body decays, and the results consist with the LHCb measurements and the earlier studies with errors. For these considered decays, since the final states are not flavour-specific, the time-dependent CPCP could be measured. We calculate six CPCP-violation observables, which can be tested in the ongoing LHCb experiment.Comment: 20 page

    Cabibbo-Kobayashi-Maskawa-favored BB decays to a scalar meson and a DD meson

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    Within the perturbative QCD approach, we investigated the Cabibbo-Kobayashi-Maskawa-favored Bβ†’Dβ€ΎSB \to \overline{D} S ("SS" denoting the scalar meson) decays on the basis of the two-quark picture. Supposing the scalar mesons are the ground states or the first excited states, we calculated the the branching ratios of 72 decay modes. Most of the branching ratios are in the range 10βˆ’410^{-4} to 10βˆ’710^{-7}, which can be tested in the ongoing LHCb experiment and the forthcoming Belle-II experiment. Some decays, such as B+β†’Dβ€Ύ(βˆ—)0a0+(980/1450)B^+ \to \overline{D}^{(*)0} a_0^+(980/1450) and B+β†’D(βˆ—)βˆ’a0+(980/1450)B^+ \to D^{(*)-} a_0^+(980/1450), could be used to probe the inner structure and the character of the scalar mesons, if the experiments are available. In addition, the ratios between the Br(B0β†’Dβ€Ύ(βˆ—)0Οƒ)Br(B^0\to \overline{D}^{(*)0}\sigma) and Br(B0β†’Dβ€Ύ(βˆ—)0f0(980))Br(B^0\to \overline{D}^{(*)0}f_0(980)) provide a potential way to determine the mixing angle between Οƒ\sigma and f0(980)f_0(980). Moreover, since in the standard model these decays occur only through tree operators and have no CPCP asymmetries, any deviation will be signal of the new physics beyond the standard model.Comment: 2 figures, 6 table

    A Mathematical Model of Economic Growth of Two Geographical Regions

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    A mathematical model of coupled differential equations is proposed to model economic growth of two geographical regions (cities, regions, continents) with flow of capital and labor between each other. It is based on two established mathematical models: the neoclassical economic growth model by Robert Solow, and the logistic population growth model. The capital flow, labor exchange and spatial heterogeneity are also incorporated in the system. The model is analyzed via equilibrium and stability analysis, and numerical simulations. It is shown that a strong attraction to the high capital region can lead to unbalanced economic growth even when the two geographical regions are similar. The model can help policy makers to decide whether the region should have an open economy or a more closed one. The results of the model can predict the trend of the trade between regions and provide a new insight into some hotly debated contemporary controversial topics
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