S01 superfluid phase transition in neutron matter with realistic nuclear potentials and modern many-body theories

Adelchi Fabrocini; Stefano Fantoni; Alexei Yu Illarionov; Kevin Schmidt

doi:10.1103/PhysRevLett.95.192501

S01 superfluid phase transition in neutron matter with realistic nuclear potentials and modern many-body theories

Adelchi Fabrocini, Stefano Fantoni, Alexei Yu Illarionov, Kevin Schmidt

Physics

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62 Scopus citations

Abstract

The S01 pairing in neutron matter is studied using realistic two- and three-nucleon interactions. The auxiliary field diffusion Monte Carlo method and correlated basis function theory are employed to get quantitative and reliable estimates of the gap. The two methods are in good agreement up to the maximum gap density and both point to a slight reduction with respect to the standard BCS value. In fact, the maximum gap is about 2.5 MeV at kF∼0.8fm-1 in BCS and 2.2-2.4 MeV at kF∼0.6fm-1 in correlated matter. In general, the computed medium polarization effects are much smaller than those previously estimated within all theories. Truncations of Argonne v8′ to simpler forms give the same gaps in BCS, provided the truncated potentials have been refitted to the same NN data set. The three-nucleon interaction provides an additional increase of the gap of about 0.35 MeV.

Original language	English (US)
Article number	192501
Journal	Physical Review Letters
Volume	95
Issue number	19
DOIs	https://doi.org/10.1103/PhysRevLett.95.192501
State	Published - Nov 4 2005

ASJC Scopus subject areas

Physics and Astronomy(all)

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10.1103/PhysRevLett.95.192501

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title = "S01 superfluid phase transition in neutron matter with realistic nuclear potentials and modern many-body theories",

abstract = "The S01 pairing in neutron matter is studied using realistic two- and three-nucleon interactions. The auxiliary field diffusion Monte Carlo method and correlated basis function theory are employed to get quantitative and reliable estimates of the gap. The two methods are in good agreement up to the maximum gap density and both point to a slight reduction with respect to the standard BCS value. In fact, the maximum gap is about 2.5 MeV at kF∼0.8fm-1 in BCS and 2.2-2.4 MeV at kF∼0.6fm-1 in correlated matter. In general, the computed medium polarization effects are much smaller than those previously estimated within all theories. Truncations of Argonne v8′ to simpler forms give the same gaps in BCS, provided the truncated potentials have been refitted to the same NN data set. The three-nucleon interaction provides an additional increase of the gap of about 0.35 MeV.",

author = "Adelchi Fabrocini and Stefano Fantoni and Illarionov, {Alexei Yu} and Kevin Schmidt",

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AU - Fabrocini, Adelchi

AU - Fantoni, Stefano

AU - Illarionov, Alexei Yu

AU - Schmidt, Kevin

PY - 2005/11/4

Y1 - 2005/11/4

N2 - The S01 pairing in neutron matter is studied using realistic two- and three-nucleon interactions. The auxiliary field diffusion Monte Carlo method and correlated basis function theory are employed to get quantitative and reliable estimates of the gap. The two methods are in good agreement up to the maximum gap density and both point to a slight reduction with respect to the standard BCS value. In fact, the maximum gap is about 2.5 MeV at kF∼0.8fm-1 in BCS and 2.2-2.4 MeV at kF∼0.6fm-1 in correlated matter. In general, the computed medium polarization effects are much smaller than those previously estimated within all theories. Truncations of Argonne v8′ to simpler forms give the same gaps in BCS, provided the truncated potentials have been refitted to the same NN data set. The three-nucleon interaction provides an additional increase of the gap of about 0.35 MeV.

AB - The S01 pairing in neutron matter is studied using realistic two- and three-nucleon interactions. The auxiliary field diffusion Monte Carlo method and correlated basis function theory are employed to get quantitative and reliable estimates of the gap. The two methods are in good agreement up to the maximum gap density and both point to a slight reduction with respect to the standard BCS value. In fact, the maximum gap is about 2.5 MeV at kF∼0.8fm-1 in BCS and 2.2-2.4 MeV at kF∼0.6fm-1 in correlated matter. In general, the computed medium polarization effects are much smaller than those previously estimated within all theories. Truncations of Argonne v8′ to simpler forms give the same gaps in BCS, provided the truncated potentials have been refitted to the same NN data set. The three-nucleon interaction provides an additional increase of the gap of about 0.35 MeV.

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S01 superfluid phase transition in neutron matter with realistic nuclear potentials and modern many-body theories

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