Investigation of nuclear matter properties by means of high energy nucleus-nucleus collisions

Symmetry energy coefficients of explicitly isospin asymmetric nuclear matter at variable densities (from 0.5ρ0 up to 2ρ0) are studied as generalized screening functions. An extended stability condition for asymmetric nuclear matter is proposed. We find the possibility of obtaining stable asymmetric nuclear matter even in some cases for which the symmetric nuclear matter limit is unstable. Skyrme-type forces are extensively used in analytical expressions of the symmetry energy coefficients derived as generalized screening functions in the four channels of the particle hole interaction producing alternative behaviors at different ρ and b (respectively, the density and the asymmetry coefficient). The spin and spin-isospin coefficients, with corrections to the usual Landau Migdal parameters, indicate the possibility of occurring instabilities with common features depending on the nuclear density and n–p asymmetry. Possible relevance for high energy heavy ions collisions and astrophysical objects is discussed.

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The Range and the Mean Free Path of High Energy Nucleons in Nuclear Matter

Progress of Theoretical Physics ◽

10.1143/ptp/5.1.141 ◽

1950 ◽

Vol 5 (1) ◽

pp. 141-142 ◽

Cited By ~ 1

Author(s):

Y. Fujimoto ◽

Y. Yamaguchi

Keyword(s):

Nuclear Matter ◽

Free Path ◽

Mean Free Path ◽

High Energy ◽

The Mean

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Collective Sideward Flow of Nuclear Matter in Violent High-Energy Heavy-Ion Collisions

Physical Review Letters ◽

10.1103/physrevlett.44.725 ◽

1980 ◽

Vol 44 (11) ◽

pp. 725-728 ◽

Cited By ~ 208

Author(s):

Horst Stöcker ◽

Jouchim A. Maruhn ◽

Walter Greiner

Keyword(s):

Nuclear Matter ◽

Heavy Ion Collisions ◽

Heavy Ion ◽

High Energy ◽

Ion Collisions

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Dileptons as a probe of excited nuclear matter

Canadian Journal of Physics ◽

10.1139/p89-202 ◽

1989 ◽

Vol 67 (12) ◽

pp. 1200-1206 ◽

Cited By ~ 3

Author(s):

Charles Gale ◽

Joseph Kapusta

Keyword(s):

Dispersion Relation ◽

Nuclear Matter ◽

Invariant Mass Distribution ◽

Center Of Mass ◽

Nucleon Nucleon ◽

High Energy ◽

Dilepton Production ◽

Electrons And Positrons ◽

Dense Nuclear Matter ◽

Mass Frame

The general features of dilepton production from nucleon–nucleon and nucleus–nucleus collisions are discussed. Estimates are made of the thermal production rates arising from incoherent nucleon–nucleon scattering and from two-pion annihilation. It may be possible to infer the pion dispersion relation in hot, dense nuclear matter by measuring the invariant mass distribution of back-to-back electrons and positrons in the center of mass frame in high energy nucleus–nucleus collisions. Comparison with recent data on p + Be → e+e−X at 4.9 GeV from the Bevalac is made.

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Thermodynamic instabilities in high energy heavy-ion collisions

Modern Physics Letters B ◽

10.1142/s021798491550092x ◽

2015 ◽

Vol 29 (18) ◽

pp. 1550092

Author(s):

A. Lavagno ◽

D. Pigato ◽

G. Gervino

Keyword(s):

Phase Transition ◽

Nuclear Matter ◽

Heavy Ion Collisions ◽

Heavy Ion ◽

High Energy ◽

Baryon Density ◽

Mechanical Instability ◽

Ion Collisions ◽

Nuclear Ground State ◽

Strangeness Content

One of the very interesting aspects of high energy heavy-ion collisions experiments is a detailed study of the thermodynamical properties of strongly interacting nuclear matter away from the nuclear ground state. In this direction, many efforts were focused on searching for possible phase transitions in such collisions. We investigate thermodynamic instabilities in a hot and dense nuclear medium where a phase transition from nucleonic matter to resonance-dominated [Formula: see text]-matter can take place. Such a phase transition can be characterized by both mechanical instability (fluctuations on the baryon density) and by chemical-diffusive instability (fluctuations on the strangeness concentration) in asymmetric nuclear matter. In analogy with the liquid–gas nuclear phase transition, hadronic phases with different values of antibaryon–baryon ratios and strangeness content may coexist. Such a physical regime could be, in principle, investigated in the future high-energy compressed nuclear matter experiments which will make it possible to create compressed baryonic matter with a high net baryon density.

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