素粒子論研究 79 巻, 5 号

THEORY OF EXCITATIONS IN A FERMION SYSTEM WITH LARGE QUNANTUM FLUCTUATIIONS : RESONATING HB APPROXIMATION AND RESONATING HB RPA

We develop a theory of excitations in a Fermion system with large quantum fluctuations that can be described by resonance of non-orthogonal HB wavefunctions with different correlation structures. First we will derive a new variation equation called the Resonating HB equation in order to determine the Resonating HB wavefunctions. Next, we will obtain a new approximation for excitations from time dependent small fluctuations of the Resonating HB ground state, i.e., the Resonating HB RPA. It gives two kinds of excitations. One is the collective excitations called vibrons due to secular vibrations of orbitals in the Res HB wavefunctions. The Res HB RPA gives many different classes of the vibrons arising from different HB wavefunctions involved in the ground state. Another kind of excitations arises from secular vibrations of the mixing coefficients of the Res HB wavefunctions. These new excitations called resonons are shown to correspond to the excited states in the Res HB theory due to the resonance of the HB wave functions. The Res HB RPA gives a unified description of the vibrons and resonons and their interactions.

原子核高励起状態上の巨大共鳴に関する微視的理論(基研長期研究会「原子核集団運動の非線形動力学」,研究会報告)

Recent development in the self-consistent microscopic theories based on the cranked thermal Hartree-Fock-Bogoliubov (THFB) approximation and the thermal random phase approximation (TRPA) is reviewed. The THFB approximation is effective in describing changes of nuclear structure far above the yrast region, and the TRPA can be applied to explain microscopically the giant dipole resonances (GDR) built on the excited states in the hot rotating nucleus. It is shown that the TRPA can be extended to take into account dissipation of single-particle levels due to thermal fluctuation effect.

SELFCONSISTENT TRANSPORT COEFFICIENTS FOR DAMPED MOTION

We apply the linear response theory to compute the coefficients for inertia, friction and local stiffness for large scale nuclear collective motion under the presence of a microscopic damping. A formulation is given in which these coefficients are defined within a locally harmonic approximation. The numerical computations are performed on the basis of a two-center shell model. It is found that zero frequency limit becomes a fair approximation for temperatures around 2 MeV. Friction is found to have a marked temperature dependence