Highlights of light meson spectroscopy at the BESIII experiment

Hadron spectroscopy provides a way to understand the dynamics of the strong interaction. For light hadron systems, only phenomenological models or lattice quantum chromodynamics (QCD) are applicable, because of the failure of perturbation expansions for QCD at low energy. Experimental data on light hadron spectroscopy are therefore crucial to provide necessary constraints on various theoretical models. Light meson spectroscopy has been studied using charmonium decays with the Beijing Spectrometer Experiment (BES) at the Beijing Electron-Positron Collider, operating at 2.0-4.6 GeV center-of-mass energy, for nearly three decades. Charmonium data with unprecedented statistics and well-defined initial and final states provide BESIII with unique opportunities to search for glueballs, hybrids and multi-quark states, as well as perform systematic studies of the properties of conventional light mesons. In this article, we review BESIII results that address these issues.

Automated summary

Hadron spectroscopy is essential for understanding the dynamics of the strong interaction, especially in light hadron systems where experimental data play a crucial role in constraining theoretical models. The Beijing Spectrometer Experiment has been studying light meson spectroscopy for nearly three decades, providing unique opportunities to search for exotic states and conduct systematic studies of conventional light mesons.