Magneto-transport measurements in a clean two-dimensional electron system confined to a wide GaAs quantum well reveal that, when the electrons occupy two electric subbands, the sequences of fractional quantum Hall states observed at high fillings (ν > 2) are distinctly different from those of a single-subband system. Notably, when the Fermi energy lies in the ground state Landau level of either of the subbands, no quantum Hall states are seen at the even-denominator ν = 5/2 and 7/2 fillings; instead the observed states are at ν = (i + p/(2p ± 1)) where i = 2, 3, and p = 1, 2, 3, and include several new states at ν = 13/5, 17/5, 18/5, and 25/7.
PACS numbers:The ground states of low-disorder two-dimensional electron systems (2DESs) at high Landau level (LL) fillings (ν > 2) have been enigmatic. Early experiments provided evidence for a unique fractional quantum Hall state (FQHS) at the even-denominator filling ν = 5/2 [1]. More recent measurements on the highest quality 2DESs have revealed a plethora of additional ground states including insulating and density-modulated phases [2][3][4][5][6][7][8]. But absent are clear sequences of odd-denominator FQHSs at ν = i + p/(2p ± 1) (where p = 1, 2, 3, ...) that are typically observed at lower fillings (i.e., when i = 0 or 1) [9]. It is believed that, in the higher LLs, the larger extent of the electron wavefunction (in the 2D plane), combined with the presence of extra nodes, leads to a modification of the (exchange-correlation) interaction effects and stabilizes the non-FQHSs at the expense of FQHSs.Meanwhile, the origin and the stability of the FQHSs at high fillings, especially those at ν = 5/2 and 12/5, have become the focus of renewed interest since these states might obey non-Abelian statistics and be useful for topological quantum computing [10]. In particular, it has been proposed that the ν =5/2 FQHS should be particularly stable in a "thick" 2DES confined to a relatively wide quantum well (QW) [11]. In a realistic, experimentally achievable system, of course, the electrons in a wide QW typically occupy two (or more) electric subbands [12]. Here we report measurements in such a system. Figure 1 highlights our main observations. In contrast to data taken in a narrow (30 nm) GaAs QW where only one electric subband is occupied ( Fig. 1(a)), data for the wider (56 nm) well (Figs. 1(b,c)) [13] do not exhibit even-denominator states at ν = 5/2 and 7/2. Instead, we observe FQHS sequences at ν = 2 + p/(2p ± 1) and 3+p/(2p±1), reminiscent of the usual composite Fermion (CF) sequences observed at lower ν around 1/2 and 3/2 (i.e., at ν = 0 + p/(2p ± 1) and ν = 1 + p/(2p ± 1)) [9]. The FQHSs we observe include states at ν = 7/3, 8/3, 12/5, 13/5, 10/3, 11/3, 17/5, 18/5, and 25/7, some of which have not been previously seen [6].Our samples were grown by molecular beam epitaxy and consist of GaAs QWs bounded on each side by undoped Al 0.24 Ga 0.76 As spacer layers and Si δ-doped layers. We studied several samples with well widths (w) ranging from 30 to 80 nm. Here we focus on...
