Strongly anisotropic transport in higher two-dimensional Landau levels

Du, Rui-Rui; Tsui, D. C.; Störmer, H. L.; Pfeiffer, L. N.; Baldwin, K. W.; West, K. W.

doi:10.1016/s0038-1098(98)00578-x

Cited by 384 publications

(478 citation statements)

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“…As the sample temperature is cooled to 16mK, as shown in Fig. 2, unlike in high density samples where the half-filled states at = 9/2, 11/2 … become strongly anisotropic [8,9], here in this low-density sample, they remain more or less isotropic. This isotropic phase at these half Landau level fillings is probably due to a lower melting temperature of the stripe phase in the low electron density limit [25].…”

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confidence: 77%

“…When a high-quality two-dimensional electron system (2DES) is placed in high magnetic fields and cooled to very low temperature, many novel quantum ground states appear, for example, the integer and fractional quantum Hall effect states [1], the composite fermions (CF) Fermi sea state [2,3], the pinned Wigner crystal states [4,5], the stripe and bubble states [6][7][8][9], etc. The fundamental physics underlying these quantum phenomena and the competition among their ground states is the strong electron-electron interactions.…”

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confidence: 99%

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Competing Quantum Hall Phases in the Second Landau Level in Low Density Limit

Pan

Serafin

Xia

et al. 2015

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Abstract:In this Rapid Communication we present the results from two high-quality, low-density GaAs quantum wells. In sample A of electron density n=5.010 10 cm -2 , anisotropic electronic transport behavior was observed at =7/2 in the second Landau level. We believe that the anisotropy is due to the large Landau level mixing effect in this sample. In sample B of density 4.110 10 cm -2 , strong 8/3, 5/2, and 7/3 fractional quantum Hall states were observed. Furthermore, our energy gap data suggest that, similar to the 8/3 state, the 5/2 state may also be spin unpolarized in the low-density limit. The results from both samples show that the strong electron-electron interactions and a large Landau level mixing effect play an import role in the competing ground states in the second Landau level.

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confidence: 77%

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confidence: 99%

Competing Quantum Hall Phases in the Second Landau Level in Low Density Limit

Pan

Serafin

Xia

et al. 2015

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“…2 demonstrates this improvement in sample A. The minima in the resistance measured along [110] at ν = 9/2 and 11/2 are much deeper, the isotropic re-entrant integer quantized Hall states in the flanks of the Landau levels are much better developed [2,3,21], and additional structure is evident. Nonetheless, these data show clearly that illumination is not an important factor in the origin or orientation of the anisotropic phases of 2D electrons in high Landau levels.…”

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confidence: 96%

“…At lower magnetic fields the higher LLs become occupied, and in the third or higher (N ≥ 2) LL no FQHE states have been observed. Recent experiments have nevertheless uncovered extraordinary transport signatures unique to the high LL regime, pointing to the existence of a new class of many-body states distinct from the incompressible quantum fluids responsible for the FQHE [2,3]. The most striking of these signatures is the rapid development, at very low temperatures, of strong anisotropies in the longitudinal resistance of the 2D electron system.…”

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confidence: 99%

An investigation of orientational symmetry-breaking mechanisms in high Landau levels

Cooper

Lilly

Eisenstein

et al. 2001

Solid State Communications

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The principal axes of the recently discovered anisotropic phases of 2D electron systems at high Landau level occupancy are consistently oriented relative to the crystal axes of the host semiconductor. The nature of the native rotational symmetry breaking field responsible for this preferential orientation remains unknown. Here we report on experiments designed to investigate the origin and magnitude of this symmetry breaking field. Our results suggest that neither micron-scale surface roughness features nor the precise symmetry of the quantum well potential confining the 2D system are important factors. By combining tilted field transport measurements with detailed self-consistent calculations we estimate that the native anisotropy energy, whatever its origin, is typically ∼ 1 mK per electron.A fundamental goal of contemporary condensed matter physics is to understand the ground state of the twodimensional electron system (2DES) and to explore its experimental signatures. In the presence of a large perpendicular magnetic field B, the kinetic energy of 2D electrons becomes quantized into discrete massively degenerate Landau levels (LLs). At high B only the lowest (N = 0) LL is occupied, and the 2DES exhibits its most spectacular phenomenon: the fractional quantized Hall effect (FQHE) [1]. At lower magnetic fields the higher LLs become occupied, and in the third or higher (N ≥ 2) LL no FQHE states have been observed. Recent experiments have nevertheless uncovered extraordinary transport signatures unique to the high LL regime, pointing to the existence of a new class of many-body states distinct from the incompressible quantum fluids responsible for the FQHE [2,3]. The most striking of these signatures is the rapid development, at very low temperatures, of strong anisotropies in the longitudinal resistance of the 2D electron system.Observed only in very high mobility samples and at temperatures below about 100 mK, the anisotropies in the longitudinal resistance are strongest near half-filling of the N = 2 and several higher Landau levels. This corresponds to Landau level filling fractions ν, defined as the ratio of the electron density N s to the degeneracy eB/h of a single spin-resolved LL, of ν = 9/2, 11/2, 13/2, etc. For 2D electron systems in GaAs/AlGaAs heterostructures grown on [001]-oriented GaAs substrates, the anisotropies are consistently disposed so that the "hard" transport direction is parallel to the [110] crystallographic direction while the "easy" direction is parallel to [110]. Although a persuasive picture of how anisotropic electronic ground states develop at high Landau level occupancy now exists, there is still no understanding of why they are consistently oriented relative to the host crystal axes. The origin and magnitude of the necessary native symmetry breaking field is the focus of this paper.The resistance anisotropy near half-filling of high LLs has been widely interpreted as evidence for chargedensity-wave (CDW) ground states. Hartree-Fock (HF) calculations [4,5] have suggested that 2D...

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“…These states are therefore also called reentrant integer quantum Hall states (RIQHS). In the case of ≥ 2, these RIQHS occur at elevated temperatures around partial filling factors˜= 1 ⁄4 and˜= 3 ⁄4, whered enotes the filling factor of the highest occupied Landau level branch [95][96][97]. If the electron temperature is low enough, a seamless transition to the IQHE is observable in Fig.…”

Section: The Bubble Phasementioning

confidence: 95%

Spin and Charge Ordering in the Quantum Hall Regime

Frieß

2016

Springer Theses

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Strongly anisotropic transport in higher two-dimensional Landau levels

Cited by 384 publications

References 9 publications

Competing Quantum Hall Phases in the Second Landau Level in Low Density Limit

Competing Quantum Hall Phases in the Second Landau Level in Low Density Limit

An investigation of orientational symmetry-breaking mechanisms in high Landau levels

Spin and Charge Ordering in the Quantum Hall Regime

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