Unquenched Meson Spectroscopy

Abstract

Quantum chromodynamics (QCD), the quantum field theory of strong interactions, is highly nonpertubative in the low-energy sector, where confinement dominates and resonance phenomena are observed. Therefore, phenomenological unquenched models based on the old ideas of the S-matrix theory give a fundamental contribution to understand the complex pattern of masses, widths and shapes of experimentally observed meson resonances. In the present thesis we employ the Resonance-Spectrum-Expansion coupled-channel model to study two enigmatic meson states, the isoscalar vector φ(2170) and the charmonium-like axial-vector X(3872). The same model is applied to describe the peculiar pattern of masses and widths of the open-charm axial-vectors - pseudovectors D1(2420) and D1(2430), and Ds1(2460) and Ds1(2536). Furthermore, a simplified Schr\"odinger model is used to study the dominant wave-function components of X(3872) near its resonance mass. Both models successfully describe the whole variety of special features observed in experiment, which are not so easily explained in QCD-inspired quenched models.