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S.G.Rohoziński, J. Dobaczewski, W. Nazarewicz University of Warsaw, University of Jyv ä skyl ä The University of Tennessee, Oak Ridge National Laboratory XVI Nuclear Physics Workshop „Pierre & Marie Curie” „Superheavy and exotic nuclei” Kazimierz Dolny, Poland, 23. – 27. September 2009.
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S.G.Rohoziński, J. Dobaczewski, W. Nazarewicz University of Warsaw, University of Jyväskylä The University of Tennessee, Oak Ridge National Laboratory XVI Nuclear Physics Workshop „Pierre & Marie Curie” „Superheavy and exotic nuclei” Kazimierz Dolny, Poland, 23. – 27. September 2009 Symmetries of the local densities
The matter is: A contemporary standard approach to the theory of nuclear structure: The density functional theory • Starting point:H – nuclear effective Hamiltonian • Original approach: HFB +LDA d3rd3r’(r,r’) (HFB) (LDA) • Generalization (a new starting point): • Construction of the Hamiltonian density • (archetype: The Skyrme Hamiltonian density)
Outline • What is the matter? • Density matrices and densities • Generalized matrices and HFB equation • Transformations of the density matrices • Symmetries of the densities • General forms of the local densities with a given symmetry • Final remarks
Density p-h and p-p matrices: (the „breve” representation of the original antisymmetric pairing tensor) r, r’ –position vectors, s, s’=+1/2,-1/2 – spin indices, t, t’ =+1/2,-1/2 – isospin indices Time and charge reversed matrices: Properties:
Spin-isospin structure of density matrices Nonlocaldensities p-h, scalar and vector: p-p, scalar and vector: k=0 (isoscalar), k=1, 2, 3 (isovector) Properties: t0=0, t1,2,3=1
Local densities (Tensor is decomosed into the trace Jk(scalar),antisymmetric partJk(vector) and symmetric traceless tensor )
Generalized density matrix: Generalized mean field Hamiltonian: Lagrange multiplier matrix
where the p-h and p-p mean field Hamiltonians are HFB equation
Transformations of density matrices Hermitian one-body operator in the Fock space: g=g+ - a single-particle operator Unitary transformation generated by G: Transformation of the nucleon field operators under U: (Black circle stands for integral and sum ) Transformation of the density matrices:
Transformation of the generalized density matrix: Generalized transformation matrix Transformed density matrix Transformed mean field Hamiltonian • Two observations • A symmetry U of H(HU=UHU+=H ) can be broken in the mean field approximation: • The symmetry of the density matrix (and the mean field Hamiltonian) is robust in the iteration process
Symmetries of the densities • The symmetry of the mean field, if appears, is, in general, only a sub-symmetry of the Hamiltonian H • When solving the HFB equation the symmetry of the density matrix should be assumed in advance • There are physical and technical reasons for the choice of a particular symmetry of the density matrix • Considered symmetries: 1. Spin-space symmetries - Orthogonal and rotational symmetries, O(3) and SO(3) - Axial symmetry SO(2), axial and mirror symmetry SO(2)xSz - Point symmetries D2h, inversion, signatures Rx,y,z(π), simplexes Sx,y,z (in the all above cases , which means that p-h and p-p densities are transformed in the same way) 2. Time reversal T 3. Isospin symmetries - p-n symmetry (no proton-neutron mixing) - p-n exchange symmetry
General forms of the densities with a given symmetry The key: construction of an arbitrary isotropic tensor field as a function of the position vector(s)r, (r ‘) (Generalized Cayley-Hamilton Theorem) A simple example • The O(3) symmetry (rotations and inversion) Independent scalars: Scalar nonlocal densities: (Pseudo)vector nonlocal densities:
Local densities: Real p-h Complex isovector p-p Vanishing pseudovector p-h and p-p Gradients of scalar functions:
Differential local densities: Scalar Vector (eris the unit vector in radial direction, Jk stands for the antisymmetric part of the (pseudo)tensor densities) All other differential densities vanish.
The SO(3) symmetry (rotations alone) (There is no difference between scalars and pseudoscalars, vectors and pseudovectors, and tensors and pseudotensors) Nonlocal densities: Scalar (without any change) Vector (pseudovector)
Local densities: Scalar Vector
Traceless symmetric tensor • Axial symmetry (symmetry axis z) SO(2) vector (in the xy plane) SO(2) scalar, S3 pseudoscalar (perpendicular to the xy plane) Tensor fields are functions of and separately
Finalremarks • The nuclear energy density functional theory is the basis of investigations of the nuclear structure at the present time (like the phenomenological mean field in the second half of the last century) • Knowledge of properties of the building blocks of the functional – densities with a given symmetry – is of the great practical importance