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Little-Bang and Femto-Nova in Nucleus-Nucleus Collisions

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arxiv 2009.03006 v1 pith:6QHFA7FF submitted 2020-09-07 hep-ph hep-exnucl-th

Little-Bang and Femto-Nova in Nucleus-Nucleus Collisions

classification hep-ph hep-exnucl-th
keywords collisionsenergyhighmatterbaryonbaryon-richcalledcanonical
verification ladder T0 review T1 audit T2 compute T3 formal T4 reserved
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We make a theoretical and experimental summary of the state-of-the-art status of hot and dense QCD matter studies on selected topics. We review the Beam Energy Scan program for the QCD phase diagram and present the current status of search for QCD Critical Point, particle production in high baryon density region, hypernuclei production, and global polarization effects in nucleus-nucleus collisions. The available experimental data in the strangeness sector suggests that a grand canonical approach in thermal model at high collision energy makes a transition to the canonical ensemble behavior at low energy. We further discuss future prospects of nuclear collisions to probe properties of baryon-rich matter. Creation of a quark-gluon plasma at high temperature and low baryon density has been called the "Little-Bang" and, analogously, a femtometer-scale explosion of baryon-rich matter at lower collision energy could be called the "Femto-Nova", which may possibly sustain substantial vorticity and magnetic field for non-head-on collisions.

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    The paradox in the canonical approach at high temperature with the Roberge-Weiss transition originates from infinite-size effects and vanishes in finite-size systems due to smearing, validating the approach for lattice QCD.