Abelian and Non-Abelian States in =2/3 Bilayer Fractional Quantum Hall Systems

Abstract

There are several possible theoretically allowed non-Abelian fractional quantum Hall (FQH) states that could potentially be realized in one- and two- component FQH systems at total filling fraction = n+ 2/3, for integer n. Some of these states even possess quasiparticles with non-Abelian statistics that are powerful enough for universal topological quantum computation, and are thus of particular interest. Here, we initiate a systematic numerical study, using both exact diagonalization and variational Monte Carlo, to investigate the phase diagram of FQH systems at total filling fraction = n+2/3, including in particular the possibility of the non-Abelian Z4 parafermion state. In = 2/3 bilayers, we determine the phase diagram as a function of interlayer tunneling and repulsion, finding only three competing Abelian states, without the Z4 state. On the other hand, in single-component systems at = 8/3, we find that the Z4 parafermion state has significantly higher overlap with the exact ground state than the Laughlin state, together with a larger gap, suggesting that the experimentally observed = 8/3 state may be non-Abelian. Our results from the two complementary numerical techniques agree well with each other qualitatively.