Identical pion intensity interferometry at sqrt(s_{NN})=2.4 GeV

J. Adamczewski-Musch; O. Arnold; C. Behnke; A. Belounnas; A. Belyaev,; J.C. Berger-Chen; J. Biernat; A. Blanco; C. Blume; M. B\"ohmer; P. Bordalo,; S. Chernenko; L. Chlad; C. Deveaux; J. Dreyer; A. Dybczak; E. Epple; L.; Fabbietti; O. Fateev; P. Filip; P. Fonte; C. Franco; J. Friese; I.; Fr\"ohlich; T. Galatyuk; J.A. Garz\'on; R. Gernh\"auser; M. Golubeva; R.; Greifenhagen; F. Guber; M. Gumberidze; S. Harabasz; T. Heinz; T. Hennino; S.; Hlavac; C. H\"ohne; R. Holzmann; A. Ierusalimov; A. Ivashkin; B. K\"ampfer,; T. Karavicheva; B. Kardan; I. Koenig; W. Koenig; B.W. Kolb; G. Korcyl; G.; Kornakov; F. Kornas; R. Kotte; A. Kugler; T. Kunz; A. Kurepin; A. Kurilkin,; P. Kurilkin; V. Ladygin; R. Lalik; K. Lapidus; A. Lebedev; L. Lopes; M.; Lorenz; T. Mahmoud; L. Maier; A. Mangiarotti; J. Markert; T. Matulewicz; S.; Maurus; V. Metag; J. Michel; D.M. Mihaylov; S. Morozov; C. M\"untz; R.; M\"unzer; L. Naumann; K. Nowakowski; M. Palka; Y. Parpottas; V. Pechenov; O.; Pechenova; O. Petukhov; K. Piasecki; J. Pietraszko; W. Przygoda; S. Ramos; B.; Ramstein; A. Reshetin; P. Rodriguez-Ramos; P. Rosier; A. Rost; A. Sadovsky,; P. Salabura; T. Scheib; H. Schuldes; E. Schwab; F. Scozzi; F. Seck; P.; Sellheim; I. Selyuzhenkov; J. Siebenson; L. Silva; Yu.G. Sobolev; S. Spataro,; S. Spies; H. Str\"obele; J. Stroth; P. Strzempek; C. Sturm; O. Svoboda; M.; Szala; P. Tlusty; M. Traxler; H. Tsertos; E. Usenko; V. Wagner; C. Wendisch,; M.G. Wiebusch; J. Wirth; D. W\'ojcik; Y. Zanevsky; P. Zumbruch

arXiv:1910.07885·nucl-ex·May 27, 2020

Identical pion intensity interferometry at sqrt(s_{NN})=2.4 GeV

J. Adamczewski-Musch, O. Arnold, C. Behnke, A. Belounnas, A. Belyaev,, J.C. Berger-Chen, J. Biernat, A. Blanco, C. Blume, M. B\"ohmer, P. Bordalo,, S. Chernenko, L. Chlad, C. Deveaux, J. Dreyer, A. Dybczak, E. Epple, L., Fabbietti, O. Fateev, P. Filip, P. Fonte, C. Franco

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TL;DR

This study measures pion-pion correlations in gold-gold collisions at 2.4 GeV to analyze the space-time structure of the emission source, revealing geometric shapes, eccentricity, and charge-sign differences across collision centralities and momenta.

Contribution

First high-statistics femtoscopy analysis at this energy, providing detailed source shape, size, and eccentricity measurements in low-energy heavy-ion collisions.

Findings

01

Ellipsoidal emission source shape perpendicular to the beam.

02

Eccentricity approaches initial eccentricity at high transverse momentum.

03

Source radii increase linearly with the number of participants.

Abstract

High-statistics $π^{-} π^{-}$ and $π^{+} π^{+}$ femtoscopy data are presented for Au+Au collisions at $s_{NN} = 2.4$ GeV, measured with HADES at SIS18/GSI. The experimental correlation functions allow the determination of the space-time extent of the corresponding emission sources via a comparison to models. The emission source, parametrized as three-dimensional Gaussian distribution, is studied in dependence on pair transverse momentum, azimuthal emission angle with respect to the reaction plane, collision centrality and beam energy. For all centralities and transverse momenta, a geometrical distribution of ellipsoidal shape is found in the plane perpendicular to the beam direction with the larger extension perpendicular to the reaction plane. For large transverse momenta, the corresponding eccentricity approaches the initial eccentricity. The eccentricity is smallest for…

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