Adiabatic theorems and applications to the quantum hall effect

Avron, J. E.; Seiler, R.; Yaffe, Laurence G.

doi:10.1007/bf01209015

Cited by 233 publications

(247 citation statements)

References 20 publications

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“…We recall the notion of adiabatic evolution [33,5]. Let U A (s) be the solution of the initial value problem:…”

Section: The Adiabatic Theorem and A Commutator Equationmentioning

confidence: 99%

“…No assumption on the spectral type of H(s) restricted to RangeP ⊥ (s) need be made, Fig. 3 [5,42], to P (s) that need not be associated with an eigenvalue, and whose rank could also be infinite. In particular, the initial data could lie in a subspace corresponding to an energy band provided it is separated by a gap from the rest of the spectrum.…”

Section: Adiabatic Theorems With a Gap Conditionmentioning

confidence: 99%

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An Adiabatic Theorem without a Gap Condition

Avron¹,

Elgart²

1999

Mathematical Results in Quantum Mechanics

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We prove the adiabatic theorem for quantum evolution without the traditional gap condition. All that this adiabatic theorem needs is a (piecewise) twice differentiable finite dimensional spectral projection. The result implies that the adiabatic theorem holds for the ground state of atoms in quantized radiation field. The general result we prove gives no information on the rate at which the adiabatic limit is approached. With additional spectral information one can also estimate this rate.

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“…We recall the notion of adiabatic evolution [33,5]. Let U A (s) be the solution of the initial value problem:…”

Section: The Adiabatic Theorem and A Commutator Equationmentioning

confidence: 99%

Section: Adiabatic Theorems With a Gap Conditionmentioning

confidence: 99%

An Adiabatic Theorem without a Gap Condition

Avron¹,

Elgart²

1999

Mathematical Results in Quantum Mechanics

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“…We aim now at the adiabatic theorem of quantum mechanics, following the article J. E. Avron, R. Seiler, L. G. Ya e (1987). Even though the theorem itself is rather old | its rst formulation goes back to Born and Fock (M. Born, V. Fock (1928)) | its proper formulation was found years later by T. Kato (1950) in the context of pertubation theory of linear operators.…”

Section: The Adiabatic Setupmentioning

confidence: 99%

“…Thouless (1987), J. E. Avron, R. Seiler, L. G. Ya e (1987)). The con guration space is a compact domain in the two dimensional plain with two holes, with two Aharonov-Bohm uxes 1 and 2 running through the holes, and again a strong magnetic eld B perpendicular to the plane, see Fig.…”

Section: The Laughlin Argumentmentioning

confidence: 99%

Geometric Properties of Transport in Quantum Hall Systems

Richter¹,

Seiler²

2000

Geometry and Quantum Physics

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“…[2]) then shows that the adiabatic evolution approximates well the physical evolution, for large values of the adiabatic parameter τ → ∞, via an estimate of the form…”

Section: Hall Conductancementioning

confidence: 99%

Towards the fractional quantum Hall effect: a noncommutative geometry perspective

Marcolli

Mathai

Noncommutative Geometry and Number Theory

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In this paper we give a survey of some models of the integer and fractional quantum Hall effect based on noncommutative geometry. We begin by recalling some classical geometry of electrons in solids and the passage to noncommutative geometry produced by the presence of a magnetic field. We recall how one can obtain this way a single electron model of the integer quantum Hall effect. While in the case of the integer quantum Hall effect the underlying geometry is Euclidean, we then discuss a model of the fractional quantum Hall effect, which is based on hyperbolic geometry simulating the multi-electron interactions. We derive the fractional values of the Hall conductance as values of orbifold Euler characteristics. We compare the results with experimental data.

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Adiabatic theorems and applications to the quantum hall effect

Cited by 233 publications

References 20 publications

An Adiabatic Theorem without a Gap Condition

An Adiabatic Theorem without a Gap Condition

Geometric Properties of Transport in Quantum Hall Systems

Towards the fractional quantum Hall effect: a noncommutative geometry perspective

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