Geometrically disordered network models, quenched quantum gravity, and critical behavior at quantum Hall plateau transitions

Gruzberg, Ilya A.; Klümper, Andreas; Nuding, W.; Sedrakyan, A.

doi:10.1103/physrevb.95.125414

Cited by 42 publications

(62 citation statements)

References 99 publications

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“…Hence, the average over randomness of the saddle points leads to the average over all configurations of the curved space [41,42], with yet to be determined functional measure. The field, which is characterizing different surfaces and by use of which one can ensure reparametrization invariance of the And, as it appeared [40], by taking equal probability 1/3 for each of the three nodes (complete reflection, complete transmission, regular scattering), the localization length index becomes ν = 2.37 ± 0.011, very close to the experimental value. In passing, we like to remark that recently the problem of the fractional quantum Hall effect on arbitrary gravitational background has attracted considerable interest [43][44][45] .…”

Section: Introductionsupporting

confidence: 62%

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Random network models with variable disorder of geometry

2019

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Recently it was shown (I. A. Gruzberg, A. Klümper, W. Nuding and A. Sedrakyan, Phys. Rev. B 95, 125414 (2017)) that taking into account random positions of scattering nodes in the network model with U (1) phase disorder yields a localization length exponent 2.37 ± 0.011 for plateau transitions in the integer quantum Hall effect. This is in striking agreement with the experimental value of 2.38 ± 0.06. Randomness of the network was modeled by replacing standard scattering nodes of a regular network by pure tunneling resp. reflection with probability p where the particular value p = 1/3 was chosen. Here we investigate the role played by the strength of the geometric disorder, i.e. the value of p. We consider random networks with arbitrary probability 0 < p < 1/2 for extreme cases and show the presence of a line of critical points with varying localization length indices having a minimum located at p = 1/3.

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Section: Introductionsupporting

confidence: 62%

“…2). To overcome this difficulty, following [40] we take for every open node either t or r to be equal to ε…”

Section: Introductionmentioning

confidence: 99%

Random network models with variable disorder of geometry

2019

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“…Our results suggest that the discrepancy between the experimental and theoretical values of ν cannot be attributed to a too regular structure of the semiclassical CC network model [48]. Why did the modified CC network [29], the Chern number calculation [31], and the study of the IQH transition in the presence of δ impurities [30] lead to different critical behavior with smaller ν? The latter two investigation used linear system sizes up to about 100L B , much smaller than our largest sizes of more than 600L B .…”

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confidence: 93%

“…We then present our results and compare them with those of Refs. [29] (1) in the clean case (W = 0). For Φ = 0 and 1, the graph shows a single band from E = −4 to 4.…”

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confidence: 99%

Integer quantum Hall transition on a tight-binding lattice

et al. 2019

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Even though the integer quantum Hall transition has been investigated for nearly four decades its critical behavior remains a puzzle. The best theoretical and experimental results for the localization length exponent ν differ significantly from each other, casting doubt on our fundamental understanding. While this discrepancy is often attributed to long-range Coulomb interactions, Gruzberg et al. [Phys. Rev. B 95, 125414 (2017)] recently suggested that the semiclassical Chalker-Coddington model, widely employed in numerical simulations, is incomplete, questioning the established central theoretical results. To shed light on the controversy, we perform a high-accuracy study of the integer quantum Hall transition for a microscopic model of disordered electrons. We find a localization length exponent ν = 2.58(3) validating the result of the Chalker-Coddington network. arXiv:1805.09958v3 [cond-mat.dis-nn]

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“…The realization that the Hall conductance is robust to impurities[1] paved the way for our understanding of the integer quantum Hall plateau transition as a problem of electron localization in a system with a diverging localization length protected by a topological invariant [2][3][4]. Even after decades of research, several aspects remain unclear, including the precise value of the localization length critical exponent [5][6][7], the agreement between single-particle numerics and experimental measurements [8][9][10], and the nature of the effective field theory at the critical point [11,12].The last decade has also seen burgeoning interest in many-body localization (MBL) [13][14][15][16][17][18][19][20], a generalization of Anderson localization to highly excited eigenstates of interacting many-body systems. However, the two fields have remained largely separated.…”

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confidence: 99%

Many-body localization in Landau-level subbands

2019

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We explore the problem of localization in topological and non-topological nearly-flat subbands derived from the lowest Landau level, in the presence of quenched disorder and short-range interactions. We consider two models: a suitably engineered periodic potential, and randomly distributed point-like impurities. We perform numerical exact diagonalization on a torus geometry and use the mean level spacing ratio r as a diagnostic of ergodicity. For topological subbands, we find there is no ergodicity breaking in both the one and two dimensional thermodynamic limits. For nontopological subbands, in constrast, we find evidence of an ergodicity breaking transition at finite disorder strength in the one-dimensional thermodynamic limit. Intriguingly, indications of similar behavior in the two-dimensional thermodynamic limit are found, as well. This constitutes a novel, continuum setting for the study of the many-body localization transition in one and two dimensions.The problem of electron localization in the quantum Hall regime has a rich history. The realization that the Hall conductance is robust to impurities[1] paved the way for our understanding of the integer quantum Hall plateau transition as a problem of electron localization in a system with a diverging localization length protected by a topological invariant [2][3][4]. Even after decades of research, several aspects remain unclear, including the precise value of the localization length critical exponent [5][6][7], the agreement between single-particle numerics and experimental measurements [8][9][10], and the nature of the effective field theory at the critical point [11,12].The last decade has also seen burgeoning interest in many-body localization (MBL) [13][14][15][16][17][18][19][20], a generalization of Anderson localization to highly excited eigenstates of interacting many-body systems. However, the two fields have remained largely separated. The presence of extended single-particle states in the Landau level has been argued to delocalize the entire many-body spectrum in the presence of interactions[21]: the topological extended states indirectly couple states localized arbitrarily far away from one other, and thus induce level repulsion across the spectrum. Numerical exact diagonalization results for electrons in the lowest Landau level (LLL) [22] are consistent with this prediction, pointing to the absence of an MBL phase in the thermodynamic limit. On the other hand, this may be due features of the LLL other than its topological character, e.g., its dimensionality.Whether or not MBL can exist in two dimensions is still an open question. As a true thermodynamic phase, it has been argued[23] to be unstable towards the proliferation of rare thermal regions in dimension d > 1 (though the issue is not settled [24]). Nonetheless, there is experimental evidence of slow thermalization or "glassiness" in finite-sized two-dimensional systems [25,26]. It is thus interesting to explore the localization properties of interacting electrons in the LLL, and clarify ...

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Geometrically disordered network models, quenched quantum gravity, and critical behavior at quantum Hall plateau transitions

Cited by 42 publications

References 99 publications

Random network models with variable disorder of geometry

Random network models with variable disorder of geometry

Integer quantum Hall transition on a tight-binding lattice

Many-body localization in Landau-level subbands

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