Sunday, April 30, 2017

Phase transition from M107 hadron physics to M89 hadron physics as counterpart for de-confinement phase transition?

Quark gluon plasma assigned to de-confinement phase transition predicted by QCD has turned out to be a problematic notion. The original expectation was that quark gluon plasma (QGP) would be created in heavy ion collisions. A candidate for QGP was discovered already at RHIC but did not have quite the expected properties such as black body spectrum behaving like an ideal liquid with long range correlations between charged particle pairs created in the collision. Then LHC discovered that this phase is created even in proton-heavy nucleus collisions. Now this phase have been discovered even in proton-proton collisions. This is something unexpected and both a challenge and opportunity to TGD.

In TGD framework QGP is replaced with quantum critical state appearing in the transition from ordinary hadron physics characterized by Mersenne prime M107 to dark variant of M89 hadron physics characterized by heff/h=n=512. At criticality partons are hybrids of M89 and M107 partons with Compton length of ordinary partons and mass m(89)≤ 512 m(107). Inequality follows from possible 1/512 fractionization of mass and other quantum numbers. The observed strangeness enhancement can be understood as a violation of quark universality if the gluons of M89 hadron physics correspond to second generation of gluons whose couplings necessarily break quark universality.

The violation of quark universality would be counterpart for the violation of lepton universality and the simplest hypothesis that the charge matrices acting on family triplets are same for quarks and leptons allows to understand also the strangeness enhancement qualitatively.

See the chapter New Physics predicted by TGD: I of "p-Adic length scale hypothesis" and the article Phase transition from M107 hadron physics to M89 hadron physics as counterpart for de-confinement phase transition? .

For a summary of earlier postings see Latest progress in TGD.

Articles and other material related to TGD.

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