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Probing QCD approach to thermal equilibrium with ultrahigh energy cosmic rays

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arxiv 1811.07728 v1 pith:4MWCB3RJ submitted 2018-11-19 hep-ph astro-ph.HE

Probing QCD approach to thermal equilibrium with ultrahigh energy cosmic rays

classification hep-ph astro-ph.HE
keywords fireballmodelsaugercontentcosmicexcessgluonshadronic
verification ladder T0 review T1 audit T2 compute T3 formal T4 reserved
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The Pierre Auger Collaboration has reported an excess in the number of muons of a few tens of percent over expectations computed using extrapolation of hadronic interaction models tuned to accommodate LHC data. Very recently, we proposed an explanation for the muon excess assuming the formation of a deconfined quark matter (fireball) state in central collisions of ultrarelativistic cosmic rays with air nuclei. At the first stage of its evolution the fireball contains gluons as well as $u$ and $d$ quarks. The very high baryochemical potential inhibits gluons from fragmenting into $u \bar u$ and $d \bar d$, and so they fragment predominantly into $s \bar s$ pairs. In the hadronization which follows this leads to the strong suppression of pions and hence photons, but allows heavy hadrons to be emitted carrying away strangeness. In this manner, the extreme imbalance of hadron to photon content provides a way to enhance the muon content of the air shower. In this communication we study theoretical systematics from hadronic interaction models used to describe the cascades of secondary particles produced in the fireball explosion. We study the predictions of one of the leading LHC-tuned models QGSJET II-04 considered in the Auger analysis.

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