Structure formation during phase transitions in strongly interacting matter

Abstract

A broad range of problems associated with phase transitions in systems characterized by the strong interaction between particles and with formation of structures is reviewed. A general phenomenological mean-field model is constructed describing phase transitions of the first and the second order to the k0=0 and k0≠ 0 states. Due to fluctuations, the phase transition to the state k0≠ 0 is the transition of the first order. Various specific features of the phase transitions to the state k0≠ 0 are considered such as the anisotropic spectrum of excitations, a possibility of the formation of various structures including running and standing waves, three-axis structures, chiral waves, pasta phases, etc. A formal transition to hydrodynamical variables is performed. Then focus is made on description of the dynamics of the order parameter at the phase transitions to the states with k0= 0 and k0≠ 0. Next the non-ideal hydrodynamical description of the phase transitions of the liquid-gas type in nuclear systems is performed. Quasiperiodic structures are developed. Next, pion condensation phase transition to the k0≠ 0 state in dense, cold or warm nuclear matter is considered and then the high temperature -- small baryon chemical potential system is studied, when baryons become completely blurred and light bosons, e.g., pions, may condense either in k0= 0 or k0≠ 0 states. Then, for scalar collective modes phenomena of the Pomeranchuk instability and the Bose condensation in k0= 0 or k0≠ 0 states are studied. Next, possibility of the condensation of Bose excitations in the k0≠ 0 state in moving media is considered. Then Bose-Einstein condensation of pions at dynamically fixed number of particles is studied and specific non-equilibrium effects are demonstrated on an example.

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