Phase separation in the large-spin t- J model
Abstract
We investigate the phase diagram of the two dimensional t- J model using a recently developed technique that allows to solve the mean-field model hamiltonian with a variational calculation. The accuracy of our estimate is controlled by means of a small parameter 1/q, analogous to the inverse spin magnitude 1/s employed in studying quantum spin systems. The mathematical aspects of the method and its connection with other large-spin approaches are discussed in details. In the large-q limit the problem of strongly correlated electron systems turns in the minimization of a total energy functional. We have performed numerically this optimization problem on a finite but large L× L lattice. For a single hole the static small-polaron solution is stable unless for small values of J, where polarons of increasing sizes have lower energy. At finite doping we recover phase separation above a critical J and for any electron density, showing that the Emery et al. picture represents the semiclassical behaviour of the t- J model. Quantum fluctuations are expected to be very important especially in the small J -- small doping region, where phase separation may also be suppressed.
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