Enhanced production of multi-strange hadrons in high-multiplicity proton-proton collisions (1606.07424v2)

Abstract: At sufficiently high temperature and energy density, nuclear matter undergoes a transition to a phase in which quarks and gluons are not confined: the Quark-Gluon Plasma (QGP) [1]. Such an extreme state of strongly-interacting QCD (Quantum Chromo-Dynamics) matter is produced in the laboratory with high-energy collisions of heavy nuclei, where an enhanced production of strange hadrons is observed [2-6]. Strangeness enhancement, originally proposed as a signature of QGP formation in nuclear collisions [7], is more pronounced for multi-strange baryons. Several effects typical of heavy-ion phenomenology have been observed in high-multiplicity proton-proton (pp) collisions [8,9]. Yet, enhanced production of multi-strange particles has not been reported so far. Here we present the first observation of strangeness enhancement in high-multiplicity pp collisions. We find that the integrated yields of strange and multi-strange particles relative to pions increases significantly with the event charged-particle multiplicity. The measurements are in remarkable agreement with p-Pb collision results [10,11] indicating that the phenomenon is related to the final system created in the collision. In high-multiplicity events strangeness production reaches values similar to those observed in Pb-Pb collisions, where a QGP is formed.

• The paper reveals that high-multiplicity pp collisions significantly enhance multi-strange hadron production, marking a novel QCD phenomenon.
• It applies Tsallis-Levy parameterization and blast-wave models to accurately analyze hadron yield distributions and spectral shapes.
• Findings challenge conventional models by suggesting that final-state dynamics, rather than initial collision energy, drive strangeness enhancement.

Overview of Enhanced Production of Multi-Strange Hadrons in High-Multiplicity Proton-Proton Collisions

The paper presented by the ALICE Collaboration examines the phenomena related to strangeness enhancement in high-multiplicity proton-proton (pp) collisions at the Large Hadron Collider (LHC). This paper focuses on the production rates of both strange and multi-strange hadrons, a subject of significant interest in understanding the dynamics of Quantum Chromodynamics (QCD) in high-energy collisions.

In heavy-ion collisions, strangeness enhancement has traditionally been interpreted as a signal of quark-gluon plasma (QGP) formation. However, analogous phenomena have also been observed in smaller systems, such as pp collisions with high particle multiplicities. The evidence presented in this investigation is the first of its kind to report the enhanced production of multi-strange particles in these conditions, marking a relevant development in the paper of QCD matter.

Key Findings and Results

The paper methodically measures the yields of various strange (K⁰_S, Λ, Λ̅) and multi-strange (Ξ, Ξ̅, Ω, Ω̅) hadrons as a function of charged-particle multiplicity in pp collisions at a center-of-mass energy of √s = 7 TeV. The ALICE detector's data demonstrates a significant increase in the production rates of these hadrons with increasing event multiplicity. Notably, the ratios of yields of strange hadrons to pions indicate a multiplicity-dependent enhancement, aligning with similar observations in proton-lead (p-Pb) and lead-lead (Pb-Pb) collisions at the LHC.

The paper employs techniques such as the Tsallis-Levy parameterization to describe the yields and employs the blast-wave model to explain the spectral shapes of hadrons. The parameters resulting from these fits suggest the presence of collective expansion properties akin to those found in larger collision systems typically characterized by hydrodynamic behavior.

Implications and Future Directions

The discovery of strangeness enhancement in high-multiplicity pp collisions without a significant dependence on center-of-mass energy points to the characteristics of the final state as the driving factor for strangeness production rather than the initial collision conditions. This finding has notable implications for theoretical models, particularly those that simulate small systems, as none could accurately capture the observed yield dependencies.

The paper hints at the persistence of QCD-related phenomena, traditionally associated with heavy-ion collisions, in smaller collision systems, suggesting a possibly novel state of QCD matter. This challenges theoretical models to accommodate these results and urges further research into the underlying microscopic processes, perhaps involving "color ropes" or other configurations beyond simple parton coalescence or string fragmentation.

Continued exploration is suggested in both theoretical and experimental domains. The paper underscores the importance of investigating higher multiplicity events and examining whether the observed scaling behavior saturates or demonstrates further distinct characteristics indicative of a thermalized QGP state in small systems. Future experiments should probe these high-density conditions to determine if there are limits to strangeness enhancement and to potentially refine statistical models to fully encompass both small and heavy systems.

Conclusion

The enhanced production of multi-strange hadrons in high-multiplicity proton-proton collisions provides a compelling window into the behavior of QCD under extreme conditions in seemingly small systems. It reveals unexpected collective behavior and strangeness enhancement commonly associated with heavy-ion physics, thus extending the landscape of hadronic interaction studies and necessitating refined models that may reshape our understanding of strong interactions. This paper lays foundational insight for advanced theoretical exploration and motivates further empirical investigations to elucidate the mechanisms underlying these findings at the LHC and beyond.