Paper detail

Spectral properties of two-body random matrix ensembles for boson systems with spin

For $m$ number of bosons, carrying spin ($\cs=\spin$) degree of freedom, in $Ω$ number of single particle orbitals, each doubly degenerate, we introduce and analyze embedded Gaussian orthogonal ensemble of random matrices generated by random two-body interactions that are spin ($S$) scalar [BEGOE(2)-$\cs$]. Embedding algebra for the BEGOE(2)-$\cs$ ensemble and also for BEGOE(1+2)-$\cs$ that includes the mean-field one-body part is $U(2Ω) \supset U(Ω) \otimes SU(2)$ with SU(2) generating spin. A method for constructing the ensembles in fixed-($m,S$) spaces has been developed. Numerical calculations show that for BEGOE(2)-$\cs$, the fixed-$(m,S)$ density of states is close to Gaussian and level fluctuations follow GOE in the dense limit. For BEGOE(1+2)-$\cs$, generically there is Poisson to GOE transition in level fluctuations as the interaction strength (measured in the units of the average spacing of the single particle levels defining the mean-field) is increased. The interaction strength needed for the onset of the transition is found to decrease with increasing $S$. Covariances in energy centroids and spectral variances are analyzed. Propagation formula is derived for the variance propagator for the fixed-$(m,S)$ ensemble averaged spectral variances. Variance propagator clearly shows, by applying the Jacquod and Stone prescription, that the BEGOE(2)-$\cs$ ensemble generates ground states with spin $S=S_{max}$. This is further corroborated by analyzing the structure of the ground states in the presence of the exchange interaction $\hat{S}^2$ in BEGOE(1+2)-$\cs$. Natural spin ordering is also observed with random interactions. Going beyond these, we also introduce pairing symmetry in the space defined by BEGOE(2)-$\cs$. Expectation values of the pairing Hamiltonian show that random interactions exhibit pairing correlations in the ground state region.