Strong isospin symmetry breaking in light scalar meson production

Abstract

Isospin symmetry breaking is discussed as a tool for studying the nature and production mechanisms of light scalar mesons. We are concerned with isospin breaking effects with an amplitude md-mu (instead of the usual md-mu), where mu and md are the u and d quark masses, whose magnitude and phase vary with energy in a resonance-like way characteristic of the K K threshold region. We consider a variety of reactions that can experimentally reveal (or have revealed) the mixing of a00(980) and f0(980) resonances that breaks the isotopic invariance due to the mass difference between K+ and K0 mesons. Experimental results on the search for a00(980)-f0(980) mixing in f1(1285) f0(980)π0π+π-π0 and η(14 05) f0(980)π0π+π-π0 decays suggest a broader perspective on the isotopic symmetry breaking effects due to the K+ and K0 mass difference. It has become clear that not only the a00(980)-f0(980) mixing but also any mechanism producing K K pairs with a definite isospin in an S wave gives rise to such effects, thus suggesting a new tool for studying the nature and production mechanisms of light scalars. Of particular interest is the case of a large isotopic symmetry breaking in the η(1405) f0(980)π0π+π-π0 decay due to the occurrence of anomalous Landau thresholds (logarithmic triangle singularities), i.e., due to the η(1405) (K* K+ K*K)(K+K-+K0 K0)π0 f0(980) π0π+π- π0 transition (where it is of fundamental importance that the K* meson has a finite width).