Bohr-Sommerfeld conditions for integrable systems with critical manifolds of focus-focus type

Ngọc, San Vũ

doi:10.1002/(sici)1097-0312(200002)53:2<143::aid-cpa1>3.0.co;2-d

Cited by 55 publications

(30 citation statements)

References 32 publications

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“…In the usual Bohr Sommerfeld conditions on a cotangent phase space, β E + 1 2 δ E is replaced by a sum of two closed forms, the first one is obtained as β E from the subsymbols and the second one is the Maslov form (cf. theorem 4.5.8 of [10]). …”

Section: Statement Of the Resultsmentioning

confidence: 98%

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Quasimodes and Bohr-Sommerfeld Conditions for the Toeplitz Operators

Charles¹

2003

Communications in Partial Differential Equations

104

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Abstract. This article is devoted to the quantization of the Lagrangian submanifold in the context of geometric quantization. The objects we define are similar to the Lagrangian distributions of the cotangent phase space theory. We apply this to construct quasimodes for the Toeplitz operators and we state the Bohr-Sommerfeld conditions under the usual regularity assumption. To compare with the Bohr-Sommerfeld conditions for a pseudodifferential operator with small parameter, the Maslov index, defined from the vertical polarization, is replaced with a curvature integral, defined from the complex polarization. We also consider the quantization of the symplectomorphisms, the realization of semi-classical equivalence between two different quantizations of a symplectic manifold and the microlocal equivalences.Let (M, ω) be a symplectic compact manifold of dimension 2n endowed with a prequantization bundle, that is a complex line bundle L → M with a Hermitian structure h and a covariant derivation ∇ whose curvature is ω. To quantize these data, we assume that M is endowed with a complex structure J which is integrable and compatible with −iω. The quantum space H k is defined as the space of the holomorphic sections of L k → M . k is any positive integer and the semi-classical limit is k → ∞. The quantum semi-classical observables are the Berezin-Toeplitz operators (cf. [2], [3], [4], [5]). The purpose of this article is to quantize the Lagrangian manifolds of M , by generalising the ansatz for the Schwartz kernel of a Toeplitz operator that we proposed in [5]. We will apply this to produce quasimodes of Toeplitz operators and deduce the Bohr-Sommerfeld conditions. Let us state this last result in the case M is 2-dimensional. Consider the Toeplitz operatorand f 1 are some functions of C ∞ (M ) and M f0+k −1 f1 is the multiplication operator by f 0 + k −1 f 1 .Assume that E 0 is a regular value of the principal symbol f 0 of (T k ) and that f −1 0 (E 0 ) is connected. Then if E belongs to some neighborhood U of E 0 , the level set f −1 (E) = Λ E is a circle.Theorem 0.1. For all sequences (E α , k α ) of U × N,where

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Section: Statement Of the Resultsmentioning

confidence: 98%

“…Indeed, we can prove that the microsupport of (v α ) is a subset of h −1 0 (C) (cf. proposition 4.4.6 of [10] for a proof in the case of pseudodifferential operators with a small parameter that we can easily adapt to our situation).…”

Section: 3mentioning

confidence: 99%

Quasimodes and Bohr-Sommerfeld Conditions for the Toeplitz Operators

Charles¹

2003

Communications in Partial Differential Equations

104

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“…Donnons ici quelqueséléments d'analyse microlocale, pour plus de détails voir par exemple [39], [40] ou [13]. Pour h 0 > 0 fixé, l'ensemble …”

Section: Outils Microlocauxunclassified

“…; avec l'argument de la dimension 1 on peut montrer ( [38], [39], [40]) qu'il y a une unique faon de prolonger la solution φ 1 le long de la courbe enévitant la singularité pour arriver sur l'ouvert U 4 ; la solution finale φ 1 diffère alors de la solution φ 4 par un facteur de phase ( [38], [39], [40]) : φ 1 = e iS + (E)/h φ 4 où la fonctions S + admet un développement asymptotique en puissance de h : S + (E) = ∞ i=0 S + j (E)h j avec des coefficients S + j qui sont C ∞ par rapportà la variable E. De la même façon on a que φ 2 = e iS − (E)/h φ 3 avec aussi une fonctions S − ayant un développement asymptotique en puissance de h :…”

Section: Secondeétape :éTude Globaleunclassified

“…Cependant le spectre du double puits reste globalement assez mystérieux. Dans l'étude des singularités de l'application moment d'un système complètement intégrable, l'opérateur de Schrödinger avec double puits est le modèle type pour les singularités non-dégénérées de type hyperbolique [38], [39] et [40]. En effet, pour un hamiltonien p : M → R tel que 0 soit valeur critique de p, et tel que les fibres dans un voisinage de 0 soient compactes et connexes et ne contiennent qu'un unique point critique nondégénéré de type hyperbolique : la fibre Λ 0 := p −1 (0) est alors un « huit » et le feuilletage dans un voisinage de la fibre singulière Λ 0 est difféomorphè a celui du double puits.…”

Section: Introductionunclassified

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Sur le spectre semi-classique d’un système intégrable de dimension 1 autour d’une singularité hyperbolique

Lablée¹

2010

Annales De La Faculté Des Sciences De Toulouse : Mathématiques

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Quantum Monodromy in Prolate Ellipsoidal Billiards

Waalkens¹,

Dullin

2002

Annals of Physics

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This is the third in a series of three papers on quantum billiards with elliptic and ellipsoidal boundaries. In the present paper we show that the integrable billiard inside a prolate ellipsoid has an isolated singular point in its bifurcation diagram and, therefore, exhibits classical and quantum monodromy. We derive the monodromy matrix from the requirement of smoothness for the action variables for zero angular momentum. The smoothing procedure is illustrated in terms of energy surfaces in action space including the corresponding smooth frequency map. The spectrum of the quantum billiard is computed numerically and the expected change in the basis of the lattice of quantum states is found. The monodromy is already present in the corresponding two-dimensional billiard map. However, the full three degrees of freedom billiard is considered as the system of greater relevance to physics. Therefore, the monodromy is discussed as a truly three-dimensional effect. C 2002 Elsevier Science (USA)

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Bohr-Sommerfeld conditions for integrable systems with critical manifolds of focus-focus type

Cited by 55 publications

References 32 publications

Quasimodes and Bohr-Sommerfeld Conditions for the Toeplitz Operators

Quasimodes and Bohr-Sommerfeld Conditions for the Toeplitz Operators

Sur le spectre semi-classique d’un système intégrable de dimension 1 autour d’une singularité hyperbolique

Quantum Monodromy in Prolate Ellipsoidal Billiards

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