Unified description of floppy and rigid rotating Wigner molecules formed in quantum dots

Restoration of broken circular symmetry is used to explore the characteristics of the ground states and the excitation spectra of rotating Wigner molecules (RWM’s) formed in two-dimensional parabolic N-electron quantum dots. In high magnetic fields, the RWM’s are floppy rotors with the energies of the magic angular momentum (L) states obeying ${aL+b/L}^{1/2}.$ Under such fields the ground-state energies (referenced to the kinetic energy in the lowest Landau level) approach the electrostatic energy of N point charges in the classical equilibrium molecular configuration. At zero field and strong interelectron repulsion, the RWM’s behave like quasiclassical rigid rotors whose energies vary as $L^2.$