Abstract

A new method for calculating the low-lying states of light nuclei is proposed: antisymmetrized molecular dynamics (AMD)--superposition of selected snapshots. In addition to the cluster features of the core nucleus, the properties of the wave of valence nucleons are well expressed in terms of a superposition of selected AMD wave functions. For $^{6}\mathrm{He}$, the binding energy and the halo nature are reproduced using effective interactions determined from a phase-shift analysis. For the deformed core cases, the three ${0}^{+}$ states of $^{10}\mathrm{Be}$ are well described. Here, the importance of solving the cooling equation for the imaginary part of the Gaussian centers for the nucleons is examined. For $^{12}\mathrm{Be}$, the newly observed $J=0$ state at $2.24\phantom{\rule{0.3em}{0ex}}\text{MeV}$ is analyzed to be the second ${0}^{+}$ state.