Crystallization in the Fractional Quantum Hall Regime Induced by Landau-level Mixing

Abstract

The interplay between strongly correlated liquid and crystal phases for two-dimensional electrons exposed to a high transverse magnetic field is of fundamental interest. Through the non-perturbative fixed phase diffusion Monte Carlo method, we determine the phase diagram of the Wigner crystal in the - plane, where is the filling factor and is the strength of Landau level mixing. The phase boundary is seen to exhibit a striking dependence, with the states away from the magic filling factors =n/(2pn+1) being much more susceptible to crystallization due to Landau level mixing than those at =n/(2pn+1). Our results explain the qualitative difference between the experimental behaviors observed in n-doped and p-doped GaAs quantum wells, and, in particular, the existence of an insulating state for <1/3 and also for 1/3 << 2/5 in low density p-doped systems. We predict that in the vicinity of =1/5 and =2/9, increasing LL mixing causes a transition not into an ordinary electron Wigner crystal but rather into a strongly correlated crystal of composite fermions carrying two vortices.