Charge Imbalance and Bilayer 2D Electron Systems at T = 1

Abstract

We use interlayer tunneling to study bilayer 2D electron systems at T = 1 over a wide range of charge density imbalance, =1-2, between the two layers. We find that the strongly enhanced tunneling associated with the coherent excitonic T = 1 phase at small layer separation can survive at least up to an imbalance of = 0.5, i.e (1, 2) = (3/4, 1/4). Phase transitions between the excitonic T = 1 state and bilayer states which lack significant interlayer correlations can be induced in three different ways: by increasing the effective interlayer spacing d/, the temperature T, or the charge imbalance, . We observe that close to the phase boundary the coherent T = 1 phase can be absent at = 0, present at intermediate , but then absent again at large , thus indicating an intricate phase competition between it and incoherent quasi-independent layer states. At zero imbalance, the critical d/ shifts linearly with temperature, while at = 1/3 the critical d/ is only weakly dependent on T. At = 1/3 we report the first observation of a direct phase transition between the coherent excitonic T = 1 bilayer integer quantum Hall phase and the pair of single layer fractional quantized Hall states at 1 = 2/3 and 2=1/3.