Effects of medium on nuclear properties in multifragmentation

De, J. N.; Samaddar, S. K.; Viñas, X.; Centelles, M.; Mishustin, I. N.; Greiner, Walter

doi:10.1103/physrevc.86.024606

Cited by 6 publications

(7 citation statements)

References 57 publications

(97 reference statements)

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“…(7) has been used [28,29] in the experimental determination of the values of the symmetry coefficients of warm dilute nuclear matter. For application in core-collapse supernova simulations, it is more insightful to have understanding about the temperature dependence of the symmetry energy of isolated nuclei or nuclei embedded in a nucleonic medium [30]. In a limited temperature domain (T ≤ 2 MeV), calculations of the symmetry energy coefficients of atomic nuclei have been attempted in a schematic model by Donati et al, [31].…”

Section: δ=0mentioning

confidence: 99%

Symmetry energy of warm nuclear systems

Agrawal

Samaddar

et al. 2014

Eur. Phys. J. A

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The temperature dependence of the symmetry energy and symmetry free energy coefficients of infinite nuclear matter and of finite nuclei is investigated. For infinite matter, both these coefficients are found to have a weaker dependence on temperature at densities close to saturation; at low but homogeneous densities, the temperature dependence becomes stronger. For finite systems, different definitions of symmetry energy coefficients are encountered in the literature yielding different values. A resolution to this problem is suggested from a global liquid-drop-inspired fit of the energies and free energies of a host of nuclei covering the entire periodic table. The hot nucleus is modeled in a subtracted finite-temperature-Thomas-Fermi framework, with dynamical surface phonon coupling to nucleonic motion plugged in. Contrary to infinite nuclear matter, a substantial change in the symmetry energy coefficients is observed for finite nuclei with temperature.

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Section: δ=0mentioning

confidence: 99%

Symmetry energy of warm nuclear systems

Agrawal

Samaddar

et al. 2014

Eur. Phys. J. A

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“…Other modifications are now under intensive theoretical and experimental investigation in multifragmentation reactions, for example, a decrease of the symmetry energy of fragments [46,47,48], and reduction of the binding energies of light clusters [56,87,88] in-medium. A calculation within a selfconsistent microscopic approach has been performed recently in [89]. Presently, we can only declare significant differences between mass distributions of SMSM, HS and FYSS models, which use different assumptions on properties of fragments, especially at low electron fractions, low temperatures and high densities.…”

Section: Mass Distributionsmentioning

confidence: 99%

A comparative study of statistical models for nuclear equation of state of stellar matter

Buyukcizmeci,

Botvina,

Mishustin

et al. 2012

Preprint

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“…where T c (X) is the critical temperature for infinite nuclear matter of isospin asymmetry X, defined as X = (ρ n − ρ p )/(ρ n + ρ p ) where ρ n and ρ p are the neutron and proton densities (for SINM, the definition of asymmetry is somewhat more subtle and given later). Since then, numerous calculations have been done to understand properties of hot nuclear matter [5,6,17] with this form of temperature-dependent interface energy. The scenario for finite nuclei is, however, different.…”

Section: Introductionmentioning

confidence: 99%

“…Since then, numerous calculations have been done to understand properties of hot nuclear matter [5,6,17] with this form of temperature-dependent interface energy. The scenario for finite nuclei is, however, different.…”

Section: Introductionmentioning

confidence: 99%

Thermal properties of the nuclear surface

Agrawal

Bandyopadhyay

et al. 2014

Phys. Rev. C

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The thermal evolution of a few thermodynamic properties of the nuclear surface like its thermodynamic potential energy, entropy and the symmetry free energy are examined for both semi-infinite nuclear matter and finite nuclei. The Thomas-Fermi model is employed. Three Skyrme interactions, namely, SkM * , SLy4 and SK255 are used for the calculations to gauge the dependence of the nuclear surface properties on the energy density functionals. For finite nuclei, the surface observables are computed from a global liquid-drop inspired fit of the energies and free energies of a host of nuclei covering the entire periodic table. The hot nuclear system is modeled in a subtracted Thomas-Fermi framework. Compared to semi-infinite nuclear matter, substantial changes in the surface symmetry energy of finite nuclei are indicated; surface thermodynamic potential energies for the two systems are, however, not too different. Analytic expressions to fit the temperature and asymmetry dependence of the surface thermodynamic potential of semi-infinite nuclear matter and the temperature dependence of the surface free energy of finite nuclei are given.

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Effects of medium on nuclear properties in multifragmentation

Cited by 6 publications

References 57 publications

Symmetry energy of warm nuclear systems

Symmetry energy of warm nuclear systems

A comparative study of statistical models for nuclear equation of state of stellar matter

Thermal properties of the nuclear surface

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