Abstract
We propose a new set of equations to determine the collective Hamiltonian including the second-order collective-coordinate operator on the basis of the adiabatic self-consistent collective-coordinate (ASCC) theory. We illustrate, with the two-level Lipkin model, that the collective operators including the second-order one are self-consistently determined. We compare the results of the calculations with and without the second-order operator and show that, without the second-order operator, the agreement with the exact solution becomes worse as the excitation energy increases, but that, with the second-order operator included, the exact solution is well reproduced even for highly excited states. We also reconsider which equations one should adopt as the basic equations in the case where only the first-order operator is taken into account, and suggest an alternative set of fundamental equations instead of the conventional ASCC equations. Moreover, we briefly discuss the gauge symmetry of the new basic equations we propose in this paper.
Highlights
In recent papers, we elucidated the relation among the higher-order collective operators, the a†a terms, and the gauge symmetry and its breaking in the adiabatic self-consistent collective-coordinate (ASCC) theory [1,2,3]
That the relation between the higher-order operators and B-terms has been revealed in Ref. [3], we propose in this paper a new set of basic equations to determine the higher-order operator, which is different from Hinohara’s prescription
We have considered the ASCC theory including the second-order collectivecoordinate operator Q(2) which consists of only A-terms, proposed a new set of basic equations to determine the collective operators including Q(2), and applied it to the two-level Lipkin model
Summary
We elucidated the relation among the higher-order collective operators, the a†a terms, and the gauge symmetry and its breaking in the adiabatic self-consistent collective-coordinate (ASCC) theory [1,2,3]. In the conventional ASCC theory without the pairing correlation, only the first-order operators consisting of A-terms are taken into account, and the contributions from the higher-order operators to the equations of motion and the inertial mass are missing. It cannot be neglected from a simple order counting in the adiabatic expansion. We first consider the case without the pairing correlation on the basis of Approach A including the second-order collectivecoordinate operator Q(2) and propose a new set of fundamental equations to determine the collective operators.
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