Though quantum chromodynamics naturally allows the existence of states beyond conventional two- and three-quark mesons and baryons, detailed mechanisms responsible for binding multi-quark states are still largely mysterious.
Tetraquarks, for example, could be tightly bound pairs of diquarks or loosely bound meson-meson molecules — or even both, depending on the production process.
The new exotic states — Zcs(4000)+, Zcs(4220)+, X(4685), and X(4630) — were observed in an almost pure sample of 24,000 B+→J/ψφK+ decays, which, as a three-body decay, may be visualized using a Dalitz plot.
“Horizontal and vertical bands indicate the temporary production of tetraquark resonances which subsequently decay to a J/ψ meson and a K+ meson or a J/ψ meson and a φ meson, respectively,” the physicists said. The most prominent vertical bands correspond to the cc̄ss̄ tetraquarks X(4140), X(4274), X(4500) and X(4700), which were first observed in June 2016.
The collaboration has now resolved two new horizontal bands corresponding to the cc̄us̄ states Zcs(4000)+ and Zcs(4220)+, and two additional vertical bands corresponding to the cc̄ss̄ states X(4685) and X(4630).
The BESIII collaboration at the Beijing Electron-Positron Collider II recently discovered the first candidate for a charged hidden-charm tetraquark with strangeness, tentatively dubbed Zcs(3985).
“It is unclear whether the new Zcs(4000)+ tetraquark can be identified with this state,” the researchers said. “Though their masses are consistent, the width of the BESIII particle is 10 times smaller. These states may have very different inner structures,” said Dr. Liming Zhang, member of the LHCb Collaboration.
“The one seen by BESIII is a narrow and longer-lived particle, and is
easier to understand with a nuclear-like hadronic molecular picture,
where two hadrons interact via a residual strong force.” SciNews
