A chiral effective lagrangian for nuclei

Furnstahl, R. J.; Serot, Brian D.; Tang, Hua-Bin

doi:10.1016/s0375-9474(96)00472-1

Cited by 383 publications

(912 citation statements)

References 84 publications

(191 reference statements)

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“…[1,3,4], the effective hadronic Lagrangians of QHD and related models are consistent with the symmetries of QCD: Lorentz invariance, parity invariance, electromagnetic gauge invariance, isospin and chiral symmetry. However, QHD calculations do not include pions explicitly.…”

Section: Introductionmentioning

confidence: 87%

Relativistic nuclear model with point-couplings constrained by QCD and chiral symmetry

et al. 2004

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We derive a microscopic relativistic point-coupling model of nuclear many-body dynamics constrained by in-medium QCD sum rules and chiral symmetry. The effective Lagrangian is characterized by density dependent coupling strengths, determined by chiral one-and two-pion exchange and by QCD sum rule constraints for the large isoscalar nucleon self-energies that arise through changes of the quark condensate and the quark density at finite baryon density. This approach is tested in the analysis of the equations of state for symmetric and asymmetric nuclear matter, and of bulk and single-nucleon properties of finite nuclei. In comparison with purely phenomenological mean-field approaches, the built-in QCD constraints and the explicit treatment of pion exchange restrict the freedom in adjusting parameters and functional forms of density dependent couplings. It is shown that chiral (two-pion exchange) fluctuations play a prominent role for nuclear binding and saturation, whereas strong scalar and vector fields of about equal magnitude and opposite sign, induced by changes of the QCD vacuum in the presence of baryonic matter, generate the large effective spin-orbit potential in finite nuclei.

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Section: Introductionmentioning

confidence: 87%

Relativistic nuclear model with point-couplings constrained by QCD and chiral symmetry

et al. 2004

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“…A meaningful criterion used to construct an effective Lagrangian for nuclear-physics calculations has been proposed by Furnstahl and collaborators based on the concept of "naive dimensional analysis" and "naturalness" [22][23][24][25][26]. The basic idea behind naturalness is that once the dimensionful meson fields (having units of mass) have been properly scaled using strong-interaction mass scales, the remaining dimensionless coefficients of the effective Lagrangian should all be "natural"; that is, neither too small nor too large [22,27]. Such an approach is both useful and powerful as it allows an organizational scheme based on an expansion in powers of the meson fields.…”

Section: A Relativistic Mean-field Modelsmentioning

confidence: 99%

“…In practice, however, many successful theoretical models-such as NL3 [16,17] and FSUGold [19]-arbitrarily set some of these parameters to zero. The "justification" behind these fairly ad-hoc procedure is that whereas the neglected terms are of the same order in a power-counting scheme, the full set of parameters is poorly determined by existing data, so ignoring a subset model parameters does not compromise the quality of the fit [10,22].…”

Section: A Relativistic Mean-field Modelsmentioning

confidence: 99%

Accurate calibration of relativistic mean-field models: Correlating observables and providing meaningful theoretical uncertainties

Fattoyev

Piekarewicz

2011

Phys. Rev. C

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Theoretical uncertainties in the predictions of relativistic mean-field models are estimated using a chi-square minimization procedure that is implemented by studying the small oscillations around the chi-square minimum. By diagonalizing the matrix of second derivatives, one gains access to a wealth of information-in the form of powerful correlations-that would normally remain hidden. We illustrate the power of the covariance analysis by using two relativistic mean-field models: (a) the original linear Walecka model and (b) the accurately calibrated FSUGold parametrization. In addition to providing meaningful theoretical uncertainties for both model parameters and predicted observables, the covariance analysis establishes robust correlations between physical observables. In particular, we show that whereas the correlation coefficient between the slope of the symmetry energy and the neutron-skin thickness of Lead is indeed very large, a 1% measurement of the neutron radius of Lead may only be able to constrain the slope of the symmetry energy to about 30%.

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“…The concepts and methods of effective field theory (EFT) [1][2][3][4][5] have recently elucidated the successful nuclear phenomenology of relativistic field theories of hadrons, called quantum hadrodynamics (QHD) [6][7][8][9]. The EFT framework shows how QHD models can be consistent with the symmetries of quantum chromodynamics (QCD) and can be extended to accurately reproduce its low-energy features.…”

Section: Introductionmentioning

confidence: 99%

The nuclear spin-orbit force in chiral effective field theories

1998

Self Cite

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A compelling feature of relativistic mean-field phenomenology has been the reproduction of spin-orbit splittings in finite nuclei after fitting only to equilibrium properties of infinite nuclear matter. This successful result occurs when the velocity dependence of the equivalent central potential that leads to saturation arises primarily because of a reduced nucleon effective mass. The spin-orbit interaction is then also specified when one works in a fourcomponent Dirac framework. Here the nature of the spin-orbit force in more general chiral effective field theories of nuclei is examined, with an emphasis on the role of the tensor coupling of the isoscalar vector meson (ω) to the nucleon.

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A chiral effective lagrangian for nuclei

Cited by 383 publications

References 84 publications

Relativistic nuclear model with point-couplings constrained by QCD and chiral symmetry

Relativistic nuclear model with point-couplings constrained by QCD and chiral symmetry

Accurate calibration of relativistic mean-field models: Correlating observables and providing meaningful theoretical uncertainties

The nuclear spin-orbit force in chiral effective field theories

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