Nucleon effective masses in neutron-rich matter

Li, Bao-An; Cai, Bao-Jun; Chen, Lie‐Wen; Xu, Jun

doi:10.1016/j.ppnp.2018.01.001

Cited by 173 publications

(117 citation statements)

References 489 publications

(1,166 reference statements)

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“…The second derivative of Eq. (22) and its relation to the incompressibility (K) of nuclear matter is given by [7,10]…”

Section: Discussion On Empirical Valuesmentioning

confidence: 99%

“…The properties of infinite nuclear matter have been the subject of intensive investigations for many decades, mainly because of the wide range of applications, including the properties of heavy nuclei and their excitation modes [1,2], heavy ion collisions [3], the physics of supernova explosions [4,5], and neutron stars [6]. Besides the binding energy per nucleon and the saturation density, other basic properties of nuclear matter like the effective mass of nucleons and its momentum dependence [7], the incompressibility [8], the symmetry energy and its density dependence [9], and recently the skewness [10], provide basic information on the effective interaction between nucleons in the medium. Theoretical descriptions of those and other important properties of nuclear matter have been based on Brückner's G-matrix approach [11][12][13], relativistic theories based on meson exchange [14][15][16], effective interactions of the Skyrme [17] and Landau-Migdal type [18], and effective field theories [19][20][21][22][23].…”

Section: Introductionmentioning

confidence: 99%

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Skewness of nuclear matter and three-particle correlations

Bentz

Cloët

2019

Phys. Rev. C

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We present a study of the skewness of nuclear matter, which is proportional to the third derivative of the energy per nucleon with respect to the baryon density at the saturation point, in the framework of the Landau-Migdal theory. We derive an exact relation between the skewness, the nucleon effective mass, and two-particle and three-particle interaction parameters. We also present qualitative estimates, which indicate that three-particle correlations play an important role for the skewness.

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“…The second derivative of Eq. (22) and its relation to the incompressibility (K) of nuclear matter is given by [7,10]…”

Section: Discussion On Empirical Valuesmentioning

confidence: 99%

Section: Introductionmentioning

confidence: 99%

Skewness of nuclear matter and three-particle correlations

Bentz

Cloët

2019

Phys. Rev. C

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“…Some parameters of the EOS that are crucial for neutron star properties are not well constrained by nuclear reaction or structure experiment. In particular, the value of neutron effective mass remains very uncertain [2,3]. In this paper, we focus on the role of the neutron effective mass on the high density EOS, and show that it can be tightly constrained using properties of doubly-magic nuclei, ab-initio calculations of low-density neutron matter in conjunction with astrophysical and gravitational wave observations.…”

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confidence: 99%

Constraints on Skyrme equations of state from doubly magic nuclei, ab initio calculations of low-density neutron matter, and neutron stars

et al. 2019

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We use properties of doubly-magic nuclei, ab-initio calculations of low-density neutron matter, and of neutron stars to constrain the parameters of the Skyrme energy-density functional. We find all of these properties can be reproduced within a constrained family of Skyrme parameters. The maximum mass of a neutron star is found to be sensitive to the neutron effective mass. A value of [m * n /m](ρ0) = 0.60 − 0.65 is required to obtain a maximum neutron star mass of 2.1 solar masses. Using the constrained Skyrme functional with the aforementioned effective mass, the predicted radius for a neutron star of 1.4 solar masses is 12.4(1) km and Λ = 423(40).

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“…There are different definitions of the in-medium nucleon effective mass (see, e.g., Ref. [177] for a recent review), and I mostly concentrate on the non-relativistic 'k-mass' m * n/p = m 1 +…”

Section: Isospin Splitting Of Nucleon Effective Massmentioning

confidence: 99%

“…So far, most studies favor a larger neutron effective mass than proton in a neutron-rich medium (see Table 2 of Ref. [177]), and this leads to the increasing trend of the symmetry potential with decreasing nucleon momentum [178]. However, the possibility for a larger proton effective mass than neutron in neutron-rich matter can not be completely ruled out yet.…”

Section: Isospin Splitting Of Nucleon Effective Massmentioning

confidence: 99%

Transport approaches for the description of intermediate-energy heavy-ion collisions

2019

Progress in Particle and Nuclear Physics

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The transport approach is a useful tool to study dynamics of non-equilibrium systems. For heavy-ion collisions at intermediate energies, where both the smooth nucleon potential and the hard-core nucleon-nucleon collision are important, the dynamics are properly described by two families of transport models, i.e., the Boltzmann-Uehling-Uhlenbeck approach and the quantum molecular dynamics approach. These transport models have been extensively used to extract valuable information of the nuclear equation of state, the nuclear symmetry energy, and microscopic nuclear interactions from intermediate-energy heavy-ion collision experiments. On the other hand, there do exist deviations on the predications and conclusions from different transport models. Efforts on the transport code evaluation project are devoted in order to understand the model dependence of transport simulations and well control the main ingredients, such as the initialization, the mean-field potential, the nucleon-nucleon collision, etc. A new era of accurately extracting nuclear interactions from transport model studies is foreseen. 2 from 50 MeV to 2 GeV, where the nucleon degree of freedom dominates the dynamics, and both the smooth nuclear potential and the hard-core nucleon-nucleon collisions become important. The central purpose of intermediate-energy heavy-ion collisions is to extract the equation of state (EOS) of the hot and dense nuclear matter formed during the collisions, while the uncertainties mostly come from the isospin-dependent part, i.e., the nuclear symmetry energy.In order to describe properly the dynamics of intermediate-energy heavy-ion collisions, transport approaches at this energy regime are mostly developed along two directions: the Boltzmann-Uehling-Uhlenbeck (BUU) approach and quantum molecular dynamics (QMD) approach. The BUU approach basically models the time evolution of the one-body phase-space distribution based on the BUU equation numerically using the test-particle method, and the QMD approach models the time evolution of nucleons under a many-body Hamiltonian with the wave function of each nucleon represented by a Gaussian wave packet. Both approaches can be derived from many-body theories with various approximations. Without nucleon-nucleon collisions, the BUU approach reduces to the Vlasov approach, which is similar to the TDHF approach. On the other hand, it is difficult to solve exactly the extended TDHF approach, which incorporates the collision contribution into the TDHF approach [3]. Both the BUU approach and the QMD approach include mainly three ingredients: the initialization of projectile and target nuclei, the mean-field potential for each nucleon, and the nucleon-nucleon collision in the dynamical evolution. The mean-field potential can be obtained from effective in-medium nucleon-nucleon interactions based on the Hartree or Hartree-Fock method, and in this way the microscopic nuclear interaction is related to the macroscopic nuclear EOS through the energy-density functional form.So far both the BUU appr...

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Nucleon effective masses in neutron-rich matter

Cited by 173 publications

References 489 publications

Skewness of nuclear matter and three-particle correlations

Skewness of nuclear matter and three-particle correlations

Constraints on Skyrme equations of state from doubly magic nuclei, ab initio calculations of low-density neutron matter, and neutron stars

Transport approaches for the description of intermediate-energy heavy-ion collisions

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