Ξ baryon
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| Ξ baryon | |
|---|---|
| Name | Ξ baryon |
| Composition | Strange quark, Strange quark, Up quark or Down quark |
| Statistics | Fermionic |
| Family | Baryon |
| Group | Hyperon |
| Interaction | Strong interaction, Weak interaction, Electromagnetism, Gravity |
| Antiparticle | Antixi |
| Theorized | Murray Gell-Mann, Kazuhiko Nishijima (c. 1953) |
| Discovered | Manchester University bubble chamber group (1964) |
| Mass | Ξ0: ~1.31486 GeV/c2, Ξ−: ~1.32171 GeV/c2 |
| Electric charge | Ξ0: 0 e, Ξ−: −1 e |
| Spin | 1/2 |
| Parity | +1 |
| Isospin | 1/2 |
| Strangeness | −2 |
| Lifetime | Ξ0: ~2.90×10−10 s, Ξ−: ~1.639×10−10 s |
Ξ baryon. The Ξ baryon, or cascade particle, is a type of hyperon containing two strange quarks, making it a doubly strange baryon. It is a member of the spin-1/2 ground-state octet in the eightfold way classification scheme. These particles are notable for their strangeness of −2 and their characteristic cascade decay patterns into lighter hadrons.
Overview
The Ξ baryons form an isospin doublet, consisting of the neutral Ξ0 (quark composition uss) and the negatively charged Ξ− (dss). They are heavier than the Λ and Σ hyperons but lighter than the Ω<sup>−</sup>. Their existence was a key prediction of the Quark model proposed by Murray Gell-Mann and independently by George Zweig. The study of Ξ baryons provides critical tests for QCD and effective field theories of the Strong interaction.
Discovery
The first evidence for cascade particles emerged from cosmic-ray experiments in the early 1950s. The Ξ− was definitively discovered in 1952 by a team at the University of Manchester using a cloud chamber exposed to cosmic rays at the High Altitude Research Station. The neutral Ξ0 was observed several years later in 1959 using the Bevatron at the Lawrence Berkeley National Laboratory. These discoveries were pivotal in establishing the concept of strangeness and validating the eightfold way.
Properties
Ξ baryons have a spin of 1/2 and positive parity. Their masses, approximately 1.32 GeV/c², are precisely measured by experiments like LHCb and Belle. Their magnetic moments and other static properties are calculated using lattice QCD simulations. As members of the flavor SU(3) octet, their mass relationships with the nucleon and other hyperons test SU(3) symmetry breaking. Their relatively long lifetimes, on the order of 10−10 seconds, are governed by the Weak interaction.
Decay modes
Ξ baryons decay via the weak force through sequences that inspired the "cascade" name. The primary decay for the Ξ− is into a Λ<sup>0</sup> and a π<sup>−</sup>, with the Λ0 then decaying into a Proton and another π−. The Ξ0 typically decays into a Λ0 and a π<sup>0</sup>. Rare semileptonic decays, such as Ξ → Λ l<sup>+</sup> l<sup>−</sup>, are studied at the BESIII experiment to test the Standard Model and search for CP violation.
Production
Ξ baryons are produced in high-energy collisions. They were first created in fixed-target experiments using Proton beams from the Bevatron and AGS. Today, they are copiously produced in colliders like the LHC, particularly in the forward region measured by LHCb, and in e<sup>+</sup>e<sup>−</sup> collisions at KEK's Belle II. They are also observed in heavy-ion collisions at RHIC and the ALICE detector, where their yields inform QGP properties.
Theoretical significance
The Ξ baryon is crucial for understanding strong force dynamics. Its mass and decay properties constrain models of baryon structure and Chiral symmetry breaking. As a cornerstone of the flavor octet, it tests predictions of SU(3) and the Gell-Mann–Okubo mass formula. Studies of its spin polarization in collisions probe QCD spin effects. Furthermore, Ξ baryons are key to investigating exotic states like pentaquarks and dibaryons in experiments at J-PARC and PANDA.
Category:Baryons Category:Hyperons Category:Strange matter