Exotic mesons from quantum chromodynamics with improved gluon and quark actions on the anisotropic lattice
Abstract
Hybrid (exotic) mesons, which are important predictions of quantum chromodynamics (QCD), are states of quarks and anti-quarks bound by excited gluons. First principle lattice study of such states would help us understand the role of ``dynamical'' color in low energy QCD and provide valuable information for experimental search for these new particles. In this paper, we apply both improved gluon and quark actions to the hybrid mesons, which might be much more efficient than the previous works in reducing lattice spacing error and finite volume effect. Quenched simulations were done at β=2.6 and on a =3 anisotropic 123×36 lattice using our PC cluster. We obtain 2013 26 71 MeV for the mass of the 1-+ hybrid meson qqg in the light quark sector, and 4369 37 99Mev in the charm quark sector; the mass splitting between the 1-+ hybrid meson cc g in the charm quark sector and the spin averaged S-wave charmonium mass is estimated to be 1302 37 99 MeV. As a byproduct, we obtain 1438 32 57 MeV for the mass of a P-wave 1++ uu or dd meson and 1499 28 65 MeV for the mass of a P-wave 1++ ss meson, which are comparable to their experimental value 1426 MeV for the f1(1420) meson. The first error is statistical, and the second one is systematical. The mixing of the hybrid meson with a four quark state is also discussed.
Turn this paper into a full lesson
ArcXiv compiles a staged curriculum from this paper: 8-12 lessons across beginner → advanced, synthesised section guides, visuals, flashcards, a quiz, exercises, and on-demand deep dives per section. Grounded in the abstract, never invented.