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Spin polarization phenomena in dense nuclear matter

Spin polarization phenomena in dense nuclear matter. Alexander Isayev Kharkov Institute of Physics and Technology Ukraine. OVERVIEW AND MOTIVATION The spontaneous appearance of spin polarized states in nuclear matter is the topic of a great current interest .

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Spin polarization phenomena in dense nuclear matter

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  1. Spin polarization phenomena in dense nuclear matter Alexander Isayev Kharkov Institute of Physics and Technology Ukraine

  2. OVERVIEW AND MOTIVATION • The spontaneous appearance of spin polarized states in nuclearmatter is the topic of a great current interest. • Could nuclear matter, formed in heavy ion collisions at high and intermediate energies, undergo a phase transition to a spin polarized state?

  3. OVERVIEW AND MOTIVATION • The spontaneous appearance of spin polarized states in nuclearmatter is the topic of a great current interest. • Could nuclear matter, formed in heavy ion collisions at high and intermediate energies, undergo a phase transition to a spin polarized state? • Spin correlations in the medium significantlyinfluence the neutrino cross section and neutrino luminocity. Hence, different scenarios ofsupernova explosion and cooling of neutron stars can be realized, depending on whether nuclear matter is spin polarized or not.

  4. OVERVIEW AND MOTIVATION Precisely:Nucleons possess spin. Hence,nuclear matter is a paramagnetic medium and under loweringtemperature or changing density nuclear matter can undergo a phasetransition to the state with nonequal numbers ofspin-up and spin-down nucleons: spin polarized state. Usually: majority of neutron spins are aligned in the same direction as majority of proton spins (like ferromagnetic ordering). Another possibility: majorityof neutron spins and majority of proton spins have the opposite directions (like antiferromagnetic ordering). Main emphasis:the structure of aground state of nuclear matter, whether it is spin polarized ornot and what type of spin ordering can be realized.

  5. OVERVIEW AND MOTIVATION The possibility of ferromagnetic phase transition in nuclear and neutron matter: Calculations of magnetic susceptibility with Skyrme effective forces A. Viduarre, J. Navarro, and J. Bernabeu, Astron. Astrophys. 135, 361 (1984). Ferromagnetic transition occurs at The Fermi liquid criterion for the ferromagnetic instability in nuclear matter with Skyrme interaction is reached at being nuclear matter saturation density. S. Reddy, M. Prakash, J.M. Lattimer, and J.A. Pons, Phys. Rev. C 59, 2888 (1999).

  6. In the models with realisticnucleon-nucleon (NN) interaction the ferromagnetic phasetransition seems to be suppressed up todensities well above. I. Vidana, A. Polls, and A. Ramos,Phys.Rev. C 65, 035804 (2002). S. Fantoni, A. Sarsa, and E. Schmidt, Phys. Rev.Lett.87, 181101 (2001).

  7. Here: the study of spin polarizability of nuclear matter with theuse of effective NN interaction (Skyrme, Gogny effectiveforces). Framework for consideration: Fermi liquid (FL)descriptionof nuclear matter, allowing to obtain theself-consistent equations for the order parameters, and, aftersolving them, to calculate the free energy and to make conclusionsconcerning thermodynamic stability of different phases.

  8. Basics of Formalism Normal states of nuclear matter are described by the normal distribution function of nucleons The matrix self-consistent equation for in the state of thermodynamic equilibrium The single-particle energy and is the density matrix of the system

  9. Structure of the normal distribution function and single particle energy are the Pauli matrices in spin and isospin spaces Normalization conditions for the distribution functions - the isospin asymmetry parameter FM spin order parameter AFM spin order parameter In symmetric nuclear matterwith FM ordering: AFM ordering:

  10. The energy functional of the system: FL amplitudes describe density, spin, isospin and spin-isospin correlations in nuclear medium.

  11. Self-consistent equations Set of integral equations to be solved self-consistently. Numerical procedure: iterations on the Gaussian grid in momentum space until convergence with required accuracy is achieved.

  12. Amplitude of NN interaction for Skyrme effective force In numerical calculations:SLy4, SkI3, SkI5 parametrizations Amplitude of NN interaction for Gogny effective force Two Gaussian terms reflect the finite range characterof the Gogny interaction.In numerical calculations: D1S force. Neutron and proton spin polarization parameters:

  13. SLy4: 1. Antiparallel ordering only! 2. Even small admixture of protons to neutron matter strongly decreases the onset density of spin instability. 3. Protons become totally polarized in a narrow density domain at strong isospin asymmetry, unlike to neutrons. Neutron and proton spin polarization parameters asfunctions of density at zero temperature

  14. SkI5: 1. Parallel ordering only! 2. Small admixture of protons to neutron matter insignificantly change the onset density of spin instability. Neutron and proton spin polarization parameters asfunctions of density at zero temperature

  15. The energy gain per nucleon is decreased with isospin asymmetry for SLy4 force while it is increased for SkI5 force. Total energy per nucleon, measured from its value in the normal state, as a function of density at T=0

  16. SkI3: 1. Transient behavior from antiparallel ordering to parallel ordering under increasing density. 2. There are no long tails in the density profile of neutrons at strong isospin asymmetry. 3. The energy gain is increasing function of isospin asymmetry at the given density.

  17. Symmetric nuclear matter AFM spin polarization parameter as a function ofdensity at zero temperature for D1S Gogny force and SkM*, SGII Skyrme forces. For D1S force only AFM spin ordering is realized and there are no solutions, corresponding to FM spin ordering.

  18. Total energy per nucleon, measured from itsvalue in the normal state, for the AFM spin state as a functionof density at zero temperature for D1S Gogny force and SkM*, SGII Skyrme forces.

  19. CONCLUSIONS Thus, modern effective nuclear forces being relevant for calculations at wide range of isospin asymmetries and high densities provide us with different possible scenarios of a phase transition to a spin polarized state in dense nuclear matter: a) nuclear matter with SLy4 Skyrme and D1S Gogny interactions undergoes at some critical density a phase transition to a spin polarized state with the oppositely directed spins of neutrons and protons; b) for SkI5 interaction, a spin polarized state with the like-directed neutron and proton spins is formed; c) nuclear matter with SkI3 interaction under increasing density, at first, undergoes a phase transition to the state with the opposite directions of neutron and proton spins, which goes over at larger density to the state with the same direction of nucleon spins.

  20. The different behavior at high densities of the interaction amplitudes, describing spin-spin and spin-isospin correlations, lays behind this divergence in calculations with different effective potentials. These results clearly indicate the necessity to construct a new generation of the energy functionals with the properly constrained time-odd part. Probably, these constraints will be obtained from the data on the time decay of magnetic field of isolated neutron stars. S.B. Popov and M.E. Prokhorov, Surveys in High Energy Physics 15, (2001)381.

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