Connecting the Reentrant Insulating Phase and the Zero-Field Metal-Insulator Transition in a 2D Hole System

Qiu, Richard L.J.; Gao, Xuan; Pfeiffer, L. N.; West, K. W.

doi:10.1103/physrevlett.108.106404

Cited by 22 publications

(36 citation statements)

References 41 publications

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“…Although strong electron-electron interactions are believed to be an essential factor in the origin of this MIT in 2D, the effects of disorder seem to be non-negligible and must be incorporated in order to reconcile the subtle differences in all the 2D MIT experiments over a range of disorder and interaction strength [2,3,[13][14][15]. While the understanding of the 2D MIT in the critical regime continues to advance [13][14][15][16][17], the mechanism of the 2D metallic conduction in the metallic regime (resistivity <<h/e 2 ) remains an outstanding problem under debate [4,18]. Since metallic transport is the central phenomenon that challenges conventional wisdom based on localization and weakly interacting Fermi liquid theory, its understanding would shed light on the 2D MIT and transport of correlated 2D electron fluids in general.…”

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Impact of short-range scattering on the metallic transport of strongly correlated two-dimensional holes in GaAs quantum wells

et al. 2014

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Understanding the non-monotonic behavior in the temperature dependent resistance, R(T), of strongly correlated two-dimensional (2D) carriers in clean semiconductors has been a central issue in the studies of 2D metallic states and metal-insulator-transitions. We have studied the transport of high mobility 2D holes in 20nm wide GaAs quantum wells (QWs) with varying short-range disorder strength by changing the Al fraction x in the Al x Ga 1-x As barrier. Via varying the short range interface roughness and alloy scattering, it is observed that increasing x suppresses both the strength and characteristic temperature scale of the 2D metallicity, pointing to the distinct role of short-range versus long-range disorder in the 2D metallic transport in this correlated 2D hole system with interaction parameter r s~ 20.PACS Numbers: 71.30.+h, 73.63.Hs For the past thirty years, two-dimensional (2D) quantum systems have been a rich area of concentrated study for both theorists and experimentalists to explore the interplay between Coulomb interaction and disorder effects [1][2][3][4]. In the case of 2D electrons with ultra-low density and weak disorder, the quantum and strongly interacting nature of the systems becomes so prominent that various complex quantum phases and phase transitions may exist according to theory [5][6][7][8][9][10][11]. Obtaining a clear understanding of such strongly correlated 2D systems thus remains to be extremely important in the field of many-body physics.In 2D electron or hole samples with high mobility, an intriguing metal to insulator transition (MIT) was observed in zero magnetic field (B=0) with the carrier density as the tuning parameter [2,3,12]. Although strong electron-electron interactions are believed to be an essential factor in the origin of this MIT in 2D, the effects of disorder seem to be non-negligible and must be incorporated in order to reconcile the subtle differences in all the 2D MIT experiments over a range of disorder and interaction strength [2,3,[13][14][15]. While the understanding of the 2D MIT in the critical regime continues to advance [13][14][15][16][17], the mechanism of the 2D metallic conduction in the metallic regime (resistivity <

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Impact of short-range scattering on the metallic transport of strongly correlated two-dimensional holes in GaAs quantum wells

et al. 2014

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“…[T * -activation energy; ν = 1 is for Arrhenius; ν = 1/3 and 1/2 for variable range hoppings (VRH) [2,9]]. Therefore, a systems with minimal disorder is required so that interaction remains dominant even for r s > 37.We note that the rigorous requirement for the low disorder can be alleviated in the fractional quantum Hall regime in a strong magnetic field where peculiar insulating phases characterized also by activated conductance, near filling factors 1/5, 1/3, and 1, have been considered as candidates for a WC [11][12][13][14]. However, the electron wavefunctions and interaction potentials are radically modified by the large field and the many-electron states are drastically altered.…”

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Experimental study of two-dimensional quantum Wigner solid in zero magnetic field

Huang¹,

Pfeiffer²,

West³

2014

AIP Conference Proceedings

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We report the first experimental observation of a characteristic nonlinear threshold behavior from dc dynamical response as an evidence for a Wigner crystallization in high-purity GaAs 2D hole systems in zero magnetic field. The system under increasing current drive exhibits voltage oscillations with negative differential resistance. They confirm the coexistence of a moving crystal along with striped edge states as observed for electrons on helium surfaces. However, the threshold is well below the typical classical levels due to a different pinning and depinning mechanism that is possibly related to a quantum process.In strongly correlated many electron systems, remarkable manifestations of quantum physics emerge in response to strong inter-particle Coulomb energy (E C ). The Fractional Quantum Hall (FQH) [1] state (with filling factors of odd and even denominators) and Mott insulators [2] are good examples. The most prominent interaction-driven effect is the Wigner crystallization (WC) [3] of electrons which is a solid phase of spatially separated charges settling in a form of a lattice. Such a fascinating quantum state of matter (with spin ordering) can be utilized for futuristic applications such as quantum electronics and spintronics. The classical version of the crystallization, with the Debye temperature Θ D < E C , has been demonstrated with 2D electrons on helium surfaces (EHS) [4,5]. On the other hand, the more desired quantum version with the Fermi energy E F ≪ E C ≪ Θ D has not been previously observed in 2D systems in zero magnetic field. This letter includes experimental evidence of a quantum WC obtained via an ultra-sensitive dc transport study.The nonlinear transport behaviors [6] in the absence of the significant effect of heating, as demonstrated in both WC in EHS and the charge density waves (CDW), are evidence for the sliding of spatially ordered charges under bias. Specifically, the threshold/switching behaviors accompanied by resistivity oscillations highlights a characteristic signature for the pinning and depinning of a classical WC [5]. However, in order to capture a very delicate quantum WC, much more stringent requirements have to be met with respect to both the high-resolution of dc-VI transport measurement and, especially, the high-purity of the systems. First, interaction effect must be dominant which means the interaction parameter r s = a/a B , a ratio of the Coulomb energy (E C = e 2 /(ǫ · 2a) and the Fermi energy (E F = (π 2 /m * )p), has to be at least 37 [7]. In a zero magnetic field, it can only be realized * email:jianhuang@wayne.edu with very dilute charge concentrations which is difficult to achieve in bulk materials. a = 1/ √ πp is half of the average charge spacing, a B = 2 ǫ/m * e 2 -Bohr radius, and p-charge density.Second, the dilute charge density means an enormous average carrier separation, ∝ n −1/2 , which, in the presence of a usual level of disorder, exceeds the singleparticle localization length ξ. Consequently, interaction effects are overshadowed by the single...

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“…RC network model [11,12] shows the low frequency C measurement in [2] being in the frequency independent regime. The small phase shift of charging current [10] allows an estimate of the error in C to be within 1% for the lowest hole density displaying up to 50% capacitance drop in the RIP (Fig.2 of Ref.…”

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“…The small phase shift of charging current [10] allows an estimate of the error in C to be within 1% for the lowest hole density displaying up to 50% capacitance drop in the RIP (Fig.2 of Ref. [2]). These facts exclude the resistive and slow charging explanations suggested by KP.…”

Connecting the Reentrant Insulating Phase and the Zero-Field Metal-Insulator Transition in a 2D Hole System

Abstract: We present the transport and capacitance measurements of 10nm wide GaAs quantum wells with hole densities around the critical point of the 2D metal-insulator transition (critical density pc down to 0.8×10 10 /cm 2 , rs∼36). For metallic hole density pc Show more

Cited by 22 publications

References 41 publications

Impact of short-range scattering on the metallic transport of strongly correlated two-dimensional holes in GaAs quantum wells

Impact of short-range scattering on the metallic transport of strongly correlated two-dimensional holes in GaAs quantum wells

Experimental study of two-dimensional quantum Wigner solid in zero magnetic field

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