Many-body Systems Interacting via a Two-body Random Ensemble: average energy of each angular momentum
Abstract
In this paper, we discuss the regularities of energy of each angular momentum I averaged over all the states for a fixed angular momentum (denoted as EI's) in many-body systems interacting via a two-body random ensemble. It is found that EI's with I Imin (minimum of I) or Imax have large probabilities (denoted as P(I)) to be the lowest, and that P(I) is close to zero elsewhere. A simple argument based on the randomness of the two-particle cfp's is given. A compact trajectory of the energy EI vs. I(I+1) is found to be robust. Regular fluctuations of the P(I) (the probability of finding I to be the ground state) and P(I) of even fermions in a single-j shell and boson systems are found to be reverse, and argued by the dimension fluctuation of the model space. Other regularities, such as why there are 2 or 3 sizable P(I)'s with I Imin and P(I) P(Imax)'s with I Imax, why the coefficients C defined by <EI >=CI(I+1) is sensitive to the orbits and not sensitive to particle number, are found and studied for the first time.
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