Nuclear density functional theory

被引:33
作者
Colo, G. [1 ,2 ]
机构
[1] Univ Milan, Dipartimento Fis Aldo Pontremoli, Via Celoria, Milan, Italy
[2] INFN, Sez Milano, Via Celoria, Milan, Italy
来源
ADVANCES IN PHYSICS-X | 2020年 / 5卷 / 01期
基金
欧盟地平线“2020”;
关键词
Nuclear structure; mean-field models; nuclear DFT; nuclear astrophysics; MONTE-CARLO METHODS; ATOMIC-NUCLEI; MEAN-FIELD; SKYRME PARAMETRIZATION; SUBNUCLEAR; DYNAMICS; SYSTEMS; FORCES; LIMITS; STATE;
D O I
10.1080/23746149.2020.1740061
中图分类号
O4 [物理学];
学科分类号
0702 ;
摘要
The goal of nuclear structure physics is to provide a complete understanding of the static properties of atomic nuclei, their excitation spectra, their response to external fields and their decays. While it is hard to achieve these goals within a single framework, so that there is no nuclear 'standard model', it is clear that nuclear Density Functional Theory (DFT) has probably the widest range of applicability so far. In this paper, we try to put DFT in a broader context, with frequent comparisons to electronic DFT. We also include a discussion of the relationships with ab initio methods and Effective Field Theories (EFTs) in general, as well as a short survey of the quite large number of applications. Although written with a personal and possibly biased perspective, the paper aims at fostering cross-fertilizations with other domains of science.
引用
收藏
页数:29
相关论文
共 117 条
[31]   Solving the quantum many-body problem with artificial neural networks [J].
Carleo, Giuseppe ;
Troyer, Matthias .
SCIENCE, 2017, 355 (6325) :602-605
[32]   Quantum Monte Carlo methods for nuclear physics [J].
Carlson, J. ;
Gandolfi, S. ;
Pederiva, F. ;
Pieper, Steven C. ;
Schiavilla, R. ;
Schmidt, K. E. ;
Wiringa, R. B. .
REVIEWS OF MODERN PHYSICS, 2015, 87 (03) :1067-1118
[33]   A skyrme parametrization from subnuclear to neutron star densities - Part II. Nuclei far from stabilities [J].
Chabanat, E ;
Bonche, P ;
Haensel, P ;
Meyer, J ;
Schaeffer, R .
NUCLEAR PHYSICS A, 1998, 635 (1-2) :231-256
[34]   A Skyrme parametrization from subnuclear to neutron star densities [J].
Chabanat, E ;
Bonche, P ;
Haensel, P ;
Meyer, J ;
Schaeffer, R .
NUCLEAR PHYSICS A, 1997, 627 (04) :710-746
[35]   Physics of Neutron Star Crusts [J].
Chamel, Nicolas ;
Haensel, Pawel .
LIVING REVIEWS IN RELATIVITY, 2008, 11 (1)
[36]  
Colò G, 2019, P INT SCH PHYS, V201, P95, DOI 10.3254/978-1-61499-957-7-95
[37]   Heavy nuclei: Introduction to density functional theory and variations on the theme [J].
Colo, Gianluca .
EUROPEAN PHYSICAL JOURNAL PLUS, 2018, 133 (12)
[38]   The mechanism(s) of core-collapse supernovae [J].
Couch, Sean M. .
PHILOSOPHICAL TRANSACTIONS OF THE ROYAL SOCIETY A-MATHEMATICAL PHYSICAL AND ENGINEERING SCIENCES, 2017, 375 (2105)
[39]   Measurability of the tidal polarizability of neutron stars in late-inspiral gravitational-wave signals [J].
Damour, Thibault ;
Nagar, Alessandro ;
Villain, Loic .
PHYSICAL REVIEW D, 2012, 85 (12)
[40]   Two-body contributions to the effective mass in nuclear effective interactions [J].
Davesne, D. ;
Navarro, J. ;
Meyer, J. ;
Bennaceur, K. ;
Pastore, A. .
PHYSICAL REVIEW C, 2018, 97 (04)
12345678910