Search results for "81S10"

showing 5 items of 5 documents

Quantization of Poisson Lie Groups and Applications

1996

LetG be a connected Poisson-Lie group. We discuss aspects of the question of Drinfel'd:can G be quantized? and give some answers. WhenG is semisimple (a case where the answer isyes), we introduce quantizable Poisson subalgebras ofC ∞(G), related to harmonic analysis onG; they are a generalization of F.R.T. models of quantum groups, and provide new examples of quantized Poisson algebras.

58B30Pure mathematicsGeneralizationPoisson distribution01 natural sciencesHarmonic analysissymbols.namesakeQuantization (physics)58F060103 physical sciences0101 mathematicsQuantumMathematical PhysicsComputingMilieux_MISCELLANEOUSMathematicsPoisson algebraDiscrete mathematics[MATH.MATH-RT]Mathematics [math]/Representation Theory [math.RT]Group (mathematics)010102 general mathematicsLie groupStatistical and Nonlinear Physics81S1017B37[ MATH.MATH-RT ] Mathematics [math]/Representation Theory [math.RT]symbols010307 mathematical physics16W30
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Deformation Quantization: Genesis, Developments and Metamorphoses

2002

We start with a short exposition of developments in physics and mathematics that preceded, formed the basis for, or accompanied, the birth of deformation quantization in the seventies. We indicate how the latter is at least a viable alternative, autonomous and conceptually more satisfactory, to conventional quantum mechanics and mention related questions, including covariance and star representations of Lie groups. We sketch Fedosov's geometric presentation, based on ideas coming from index theorems, which provided a beautiful frame for developing existence and classification of star-products on symplectic manifolds. We present Kontsevich's formality, a major metamorphosis of deformation qu…

High Energy Physics - TheoryMSC-class: 53D55 53-02 81S10 81T70 53D17 18D50 22Exx[PHYS.MPHY]Physics [physics]/Mathematical Physics [math-ph]FOS: Physical sciences01 natural sciences[ PHYS.HTHE ] Physics [physics]/High Energy Physics - Theory [hep-th]53D55 53-02 81S10 81T70 53D17 18D50 22Exx[MATH.MATH-MP]Mathematics [math]/Mathematical Physics [math-ph]Mathematics - Quantum Algebra0103 physical sciencesFOS: MathematicsQuantum Algebra (math.QA)[MATH.MATH-MP] Mathematics [math]/Mathematical Physics [math-ph]010306 general physicsMathematical Physics[MATH.MATH-QA] Mathematics [math]/Quantum Algebra [math.QA][ MATH.MATH-QA ] Mathematics [math]/Quantum Algebra [math.QA]010308 nuclear & particles physics[PHYS.HTHE]Physics [physics]/High Energy Physics - Theory [hep-th][ MATH.MATH-MP ] Mathematics [math]/Mathematical Physics [math-ph]Mathematical Physics (math-ph)[PHYS.MPHY] Physics [physics]/Mathematical Physics [math-ph]16. Peace & justiceQuantum AlgebraHigh Energy Physics - Theory (hep-th)[MATH.MATH-QA]Mathematics [math]/Quantum Algebra [math.QA][ PHYS.MPHY ] Physics [physics]/Mathematical Physics [math-ph][PHYS.HTHE] Physics [physics]/High Energy Physics - Theory [hep-th]
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Algebraic Quantization, Good Operators and Fractional Quantum Numbers

1995

The problems arising when quantizing systems with periodic boundary conditions are analysed, in an algebraic (group-) quantization scheme, and the ``failure" of the Ehrenfest theorem is clarified in terms of the already defined notion of {\it good} (and {\it bad}) operators. The analysis of ``constrained" Heisenberg-Weyl groups according to this quantization scheme reveals the possibility for new quantum (fractional) numbers extending those allowed for Chern classes in traditional Geometric Quantization. This study is illustrated with the examples of the free particle on the circumference and the charged particle in a homogeneous magnetic field on the torus, both examples featuring ``anomal…

PhysicsGeometric quantizationHigh Energy Physics - TheoryFree particleQuantization (signal processing)FOS: Physical sciencesStatistical and Nonlinear PhysicsMatemática Aplicada81S1081R99Ehrenfest theoremQuantum number58F06High Energy Physics - Theory (hep-th)Fractional quantum Hall effectCuantización algebraicaCuántica de números fraccionadosAlgebraic numberQuantumMathematical PhysicsMathematical physics
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The Reasonable Effectiveness of Mathematical Deformation Theory in Physics

2019

This is a brief reminder, with extensions, from a different angle and for a less specialized audience, of my presentation at WGMP32 in July 2013, to which I refer for more details on the topics hinted at in the title, mainly deformation theory applied to quantization and symmetries (of elementary particles).

PhysicsHigh Energy Physics - TheoryDark matterDeformation theoryFOS: Physical sciencesElementary particleMathematical Physics (math-ph)[MATH] Mathematics [math]16. Peace & justiceTheoretical physicsQuantization (physics)53D55 81R50 17B37 53Z05 81S10 81V25 83C57High Energy Physics - Theory (hep-th)Homogeneous spaceAnti-de Sitter space[MATH]Mathematics [math]Mathematical Physics
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Quantization on the Virasoro group

1990

The quantization of the Virasoro group is carried out by means of a previously established group approach to quantization. We explicitly work out the two-cocycles on the Virasoro group as a preliminary step. In our scheme the carrier space for all the Virasoro representations is made out of polarized functions on the group manifold. It is proved that this space does not contain null vector states, even forc≦1, although it is not irreducible. The full reduction is achieved in a striaghtforward way by just taking a well defined invariant subspace ℋ(c, h), the orbit of the enveloping algebra through the vacuum, which is irreducible for any value ofc andh. ℋ(c, h) is a proper subspace of the sp…

Pure mathematicsGroup (mathematics)Quantization (signal processing)Invariant subspaceStatistical and Nonlinear Physics81S10ManifoldGroup representation17B68Algebra58F06Null vector81R10Algebra representation22E65Mathematical PhysicsSymplectic geometryMathematics
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