Observation of a ν=1/2 fractional quantum Hall state in a double-layer electron system

Abstract: We report the observation, for the first time, of a fractional quantum Hall state at v -1/2 Landaulevel filling in a low disorder, double-layer electron system realized in a 680-A-wide GaAs/AlGaAs single quantum well. A nearly vanishing diagonal resistance and a Hall resistance quantized at 2h/e 2 to within 0.3% are observed at -15 T and -26 mK. The activated temperature dependence of the diagonal resistance minimum yields a quasiparticle excitation energy gap of 230 mK.In a standard hierarchy picture [1], ass… Show more

“…In the intermediate regime d ∼ 2 − 6, the incompressibility of the system is observed in various experiments [19][20][21][22] . However, its precise origin is still a long-standing subject.…”

“…Although such a possibility was predicted about 20 years ago [16][17][18][24][25][26][27] , convincing and comprehensive evidence directly from a microscopic description was missed until our work. Second, the previously found FQH ν T = 1/2 plateau in single wide QW experiments 19,21,22 , where the tunneling strength is taken to be considerable, is most likely to be captured by the MR Pfaffian state and in favor of a nontrivial p x + ip y pairing mechanism. By reducing the effec- tive tunneling (through tuning electron density), the system undergoes a transition from the non-Abelian MR Pfaffian to the weak p-wave pairing (331) Halperin state, while the Hall conductance keeps unchanged.…”

“…The ν T = 1 state 23 is believed to favor a symmetry-breaking state with spontaneous interlayer phase coherence, which induces a remarkable exciton condensation. The ν T = 1/2 state [19][20][21][22] has turned out to be more interesting and controversial, as it can be an Abelian Halperin FQH state, but also be a possible platform for realizing non-Abelian anyonic statistics, which has been pursued persistently in the past. [16][17][18][24][25][26][27][28][29][30][31] In this paper, we consider a two-component FQH system with N e electrons (as illustrated in Fig.…”

“…Compared to single-component systems, multicomponent FQH systems with extra degrees of freedom offer additional tunable parameters and allow the observation of richer quantum phase diagrams [14][15][16][17][18] . The internal degrees of freedom correspond to realistic experimental circumstances, for example, layers, subbands or spins in GaAs quantum wells (QWs) [19][20][21][22][23] , spins or valleys in graphene or AlAs, which lead to effective multilayers separated by layer distance d with electrons' tunneling t ⊥ between layers (Fig. 1).…”

Fractional quantum Hall bilayers at half filling: Tunneling-driven non-Abelian phase

“…In the intermediate regime d ∼ 2 − 6, the incompressibility of the system is observed in various experiments [19][20][21][22] . However, its precise origin is still a long-standing subject.…”

“…Although such a possibility was predicted about 20 years ago [16][17][18][24][25][26][27] , convincing and comprehensive evidence directly from a microscopic description was missed until our work. Second, the previously found FQH ν T = 1/2 plateau in single wide QW experiments 19,21,22 , where the tunneling strength is taken to be considerable, is most likely to be captured by the MR Pfaffian state and in favor of a nontrivial p x + ip y pairing mechanism. By reducing the effec- tive tunneling (through tuning electron density), the system undergoes a transition from the non-Abelian MR Pfaffian to the weak p-wave pairing (331) Halperin state, while the Hall conductance keeps unchanged.…”

“…The ν T = 1 state 23 is believed to favor a symmetry-breaking state with spontaneous interlayer phase coherence, which induces a remarkable exciton condensation. The ν T = 1/2 state [19][20][21][22] has turned out to be more interesting and controversial, as it can be an Abelian Halperin FQH state, but also be a possible platform for realizing non-Abelian anyonic statistics, which has been pursued persistently in the past. [16][17][18][24][25][26][27][28][29][30][31] In this paper, we consider a two-component FQH system with N e electrons (as illustrated in Fig.…”

“…Compared to single-component systems, multicomponent FQH systems with extra degrees of freedom offer additional tunable parameters and allow the observation of richer quantum phase diagrams [14][15][16][17][18] . The internal degrees of freedom correspond to realistic experimental circumstances, for example, layers, subbands or spins in GaAs quantum wells (QWs) [19][20][21][22][23] , spins or valleys in graphene or AlAs, which lead to effective multilayers separated by layer distance d with electrons' tunneling t ⊥ between layers (Fig. 1).…”

Fractional quantum Hall bilayers at half filling: Tunneling-driven non-Abelian phase

“…Celebrated examples include Skyrmions in systems with small Zeeman splitting [6,7], even-denominator FQH states [8,9], and the excitonic superfluid in bilayer systems [10]. While much effort towards the understanding of the roles of spins, layers, and subbands in the FQH regime has been made using high-quality GaAs quantum wells, experimental studies on the effects of valleys have been relatively sparse, only a few reports on 2D electrons in Si [11,12] and AlAs [13][14][15][16] available, partly due to the less impressive material quality of multi-valley semiconductors.…”

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