Frank Close scite author profile

In this paper we survey all radial and orbital excitations of the Iϭ0 and Iϭ1 nn system anticipated up to 2.1 GeV. We give detailed predictions of their quasi-two-body branching fractions and identify characteristic decay modes that can isolate quarkonia; this should be useful in distinguishing quarkonia from glueballs and hybrids. Several of the ''missing mesons'' with L q q ϭ2 and L q q ϭ3 are predicted to decay dominantly into certain Sϩ P and SϩD modes, and should appear in experimental searches for hybrids in the same mass region. We also consider the topical issues of whether some of the recently discovered or controversial meson resonances, including glueball and hybrid candidates, can be accommodated as quarkonia.

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Scalar mesons above and below 1 GeV

Törnqvist

2002

J. Phys. G: Nucl. Part. Phys.

422

431

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We show that two nonets and a glueball provide a consistent description of data on scalar mesons below 1.7 GeV. Above 1 GeV the states form a conventional qq nonet mixed with the glueball of lattice QCD. Below 1 GeV the states also form a nonet, as implied by the attractive forces of QCD, but of more complicated nature. Near the center they are (qq)3(qq) 3 in S-wave, with some qq in P-wave, but further out they rearrange as (qq) 1 (qq) 1 and finally as meson-meson states. A simple effective chiral model for such a system with two scalar nonets can be made involving two coupled linear sigma models. One of these could be looked upon as the Higgs sector of nonpertubative QCD. 1

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Isf0(1500) a scalar glueball?

1996

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Evidence for a scalar glueball

1995

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We show that the newly discovered scalar meson f 0 (1500) at LEAR has properties compatible with the lightest scalar glueball predicted by lattice QCD and incompatible with a QQ state. We suggest that decays of glueballs are into pairs of glueballs (including η, η ′ or (ππ) S ) or by mixing with nearby QQ states. The partial widths of f 0 (1500) are in accord with this hypothesis, tests of which include characteristic radiative decays to γφ, γω, γρ and the prediction of a further scalar state, f ′ 0 (1500 − 1800) which couples strongly to KK, ηη and ηη ′ .

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Dynamics and decay of heavy-light hadrons

2005

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Recent signals for narrow hadrons containing heavy and light flavours are compared with quark model predictions for spectroscopy, strong decays, and radiative transitions. In particular, the production and identification of excited charmed and cs states are examined with emphasis on elucidating the nature of 0 + and 1 + states. Roughly 200 strong decay amplitudes of D and Ds states up to 3.3 GeV are presented. Applications include determining flavour content in η mesons and the mixing angle in P and D wave states and probes of putative molecular states. We advocate searching for radially excited D * s states in B decays.

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Frank Close

Higher quarkonia

Scalar mesons above and below 1 GeV

Isf0(1500) a scalar glueball?

Evidence for a scalar glueball

Dynamics and decay of heavy-light hadrons

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