Charge deficiency, charge transport and comparison of dimensions

Avron, J. E.; Seiler, R.; Simon, Barry

doi:10.1007/bf02102644

Cited by 162 publications

(289 citation statements)

References 40 publications

(54 reference statements)

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“…The hallmark of localization is rapid (even exponential) decay of G E (x, y) at energies in the spectrum, though in this case it occurs with pre-factors which are not uniform in space and diverge at a dense countable set of eigenvalues. Rapid decay of the Green function is related to the non-spreading of wave packets supported in the corresponding energy regimes and various other manifestations of localization whose physical implications have been extensively studied in regards to the conductive properties of metals [8,55,73,1,54] and in particular to the quantum Hall effect [36,57,10,12,3].…”

mentioning

confidence: 99%

Moment analysis for localization in random Schrödinger operators

et al. 2005

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Abstract. We study localization effects of disorder on the spectral and dynamical properties of Schrödinger operators with random potentials. The new results include exponentially decaying bounds on the transition amplitude and related projection kernels, including in the mean. These are derived through the analysis of fractional moments of the resolvent, which are finite due to the resonance-diffusing effects of the disorder. The main difficulty which has up to now prevented an extension of this method to the continuum can be traced to the lack of a uniform bound on the Lifshitz-Krein spectral shift associated with the local potential terms. The difficulty is avoided here through the use of a weak-L 1 estimate concerning the boundary-value distribution of resolvents of maximally dissipative operators, combined with standard tools of relative compactness theory.

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confidence: 99%

Moment analysis for localization in random Schrödinger operators

et al. 2005

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“…Simon (1994a), avoiding the language of non-commutative geometry completely. Note that the operator U de ned by m ultiplication with u := X 1 + iX 2 jX 1 + iX 2 j (14) is the gauge transformation related to unit ux tube piercing the IR 2 at the origin.…”

Section: The Laughlin Argumentmentioning

confidence: 99%

“…We consider now an application of the index approach t o a quantum Hall system, following J. E. Avron, R. Seiler, B. Simon (1994a). Our model describes non relativistic, non interacting fermions in the punctured plane C n f a g , a 2 C, with random impurities.…”

Section: Index Approach To the Qhementioning

confidence: 99%

Geometric Properties of Transport in Quantum Hall Systems

Richter¹,

Seiler²

2000

Geometry and Quantum Physics

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“…Later theoretical investigations showed that a topological phenomenon underlies this quantization: the integer n in the above formula was shown to be the first Chern number of a vector bundle, naturally associated to the quantum system [27,1,2]. The only role played by the magnetic field in quantum Hall systems is that of breaking time-reversal symmetry: if the system were time-reversal symmetric, then the Hall conductivity would vanish, and the system would remain in an insulating state.…”

Section: Introductionmentioning

confidence: 99%

Advances in Quantum Mechanics

Michelangeli¹,

Dell’Antonio²

2017

Springer INdAM Series

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The use of topological invariants to describe geometric phases of quantum matter has become an essential tool in modern solid state physics. The first instance of this paradigmatic trend can be traced to the study of the quantum Hall effect, in which the Chern number underlies the quantization of the transverse Hall conductivity. More recently, in the framework of time-reversal symmetric topological insulators and quantum spin Hall systems, a new topological classification has been proposed by Fu, Kane and Mele, where the label takes value in Z 2 . We illustrate how both the Chern number c ∈ Z and the Fu-Kane-Mele invariant δ ∈ Z 2 of 2-dimensional topological insulators can be characterized as topological obstructions. Indeed, c quantifies the obstruction to the existence of a frame of Bloch states for the crystal which is both continuous and periodic with respect to the crystal momentum. Instead, δ measures the possibility to impose a further time-reversal symmetry constraint on the Bloch frame.

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Charge deficiency, charge transport and comparison of dimensions

Cited by 162 publications

References 40 publications

Moment analysis for localization in random Schrödinger operators

Moment analysis for localization in random Schrödinger operators

Geometric Properties of Transport in Quantum Hall Systems

Advances in Quantum Mechanics

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