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100   $a20150126d2014      u|             0
101 0 $aeng
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181   $ctxt
182   $cc
183   $acr
200 10$aLie Theory and Its Applications in Physics$b[electronic resource] $eVarna, Bulgaria, June 2013 /$fedited by Vladimir Dobrev
205   $a1st ed. 2014.
210  1$aTokyo :$cSpringer Japan :$cImprint: Springer,$d2014.
215   $a1 online resource (554 p.)
225 1 $aSpringer Proceedings in Mathematics & Statistics,$x2194-1009 ;$v111
300   $aDescription based upon print version of record.
311   $a4-431-55284-7 
320   $aIncludes bibliographical references.
327   $aPreface; Acknowledgments; Contents; List of Participants; Part I Plenary Talks; Revisiting Trace Anomalies in Chiral Theories; 1 Introduction; 2 One-Loop Trace Anomaly in Chiral Theories; 3 Pontryagin Density and Supersymmetry; 3.1 Minimal Supergravity; 3.2 Other Nonminimal Supergravities; References; Complete T-Dualization of a String in a Weakly Curved Background; 1 Bosonic String in the Weakly Curved Background; 2 Partial T-Dualization; 2.1 The Partially T-Dualized Action; 3 The Total T-Dualization of the Initial Action; References; Modular Double of the Quantum Group SLq(2,R)
327   $a1 Definitions2 Weyl Pair; 3 Explicit Realization; 4 Representation ?s; 5 Quantum Dilogarithm; 6 Decomposition of  ?s1 ?s2 ; References; Physical Ageing and New Representations of Some Lie Algebras of Local Scale-Invariance; 1 Introduction; 2 Logarithmic Representations; 2.1 Schrödinger Algebra; 2.2 Conformal Galilean Algebra; 2.3 Exotic Conformal Galilean Algebra; 2.4 Ageing Algebra; 2.5 Discussion; 3 Large-Distance Behaviour and Causality; 3.1 Schrödinger Algebra; 3.2 Conformal Galilean Algebra; 3.3 Discussion; References; New Type of N=4 Supersymmetric Mechanics; 1 Introduction
327   $a2 SU(2|1) Superspace2.1 Deformed Superspace; 2.2 Covariant Derivatives; 3 The Supermultiplet (1, 4, 3); 4 The (1, 4, 3) Oscillator Model; 4.1 Wave Functions; 4.2 Spectrum and SU(2|1) Representations; 5 The Supermultiplet (2,4,2); 5.1 Chiral Subspaces; 5.2 SU(2|1) Invariant Lagrangian; 5.3 Quantum Generators; 6 Simplified Model on a Complex Plane; 6.1 Wave Functions and Spectrum; 7 Summary and Outlook; References; Vector-Valued Covariant Differential Operators for the Möbius Transformation; 1 A Family of Vector-Valued Functional Identities; 2 Three Equivalent Formulations
327   $a2.1 Covariance of SL(2,R) for Vector-Valued Functions2.2 Conformally Covariant Differential Operators; 2.3 Branching Laws of Verma Modules; 3 Rankin-Cohen Brackets; 3.1 Homogeneous Line Bundles over P1C; 3.2 Rankin-Cohen Bidifferential Operator; 4 Holomorphic Trick; 4.1 Restriction to a Totally Real Submanifold; 4.2 Identities of Jacobi Polynomials; 4.3 Proof of Theorem A; 4.4 Scalar-Valued Case; References; Semi-classical Scalar Products in the Generalised SU(2) Model; 1 Introduction; 2 Algebraic Bethe Ansatz for Integrable Models with su(2) R-Matrix
327   $a3 Determinant Formulas for the Inner Product4 Field Theory of the Inner Product; 4.1 The A-Functional in Terms of Free Fermions; 4.2 Bosonic Theory and Coulomb Gas; 4.3 The Thermodynamical Limit; 4.4 Coarse-Graining; 4.5 The First Two Orders of the Semi-classical Expansion; 5 Discussion; References; Weak Poisson Structures on Infinite Dimensional Manifolds and Hamiltonian Actions; 1 Introduction; 2 Infinite Dimensional Poisson Manifolds; 2.1 Locally Convex Manifolds; 2.2 Weak Poisson Manifolds; 2.3 Examples of Weak Poisson Manifolds; 2.4 Poisson Maps; 3 Momentum Maps
327   $a3.1 Momentum Maps as Poisson Morphisms
330   $aTraditionally, Lie theory is a tool to build mathematical models for physical systems. Recently, the trend is towards geometrization of the mathematical description of physical systems and objects. A geometric approach to a system yields in general some notion of symmetry which is very helpful in understanding its structure. Geometrization and symmetries are meant in their widest sense, i.e., representation theory, algebraic geometry, infinite-dimensional Lie algebras and groups, superalgebras and supergroups, groups and quantum groups, noncommutative geometry, symmetries of linear and nonlinear PDE, special functions, and others. Furthermore, the necessary tools from functional analysis and number theory are included. This is a big interdisciplinary and interrelated field. Samples of these fresh trends are presented in this volume, based on contributions from the Workshop "Lie Theory and Its Applications in Physics" held near Varna (Bulgaria) in June 2013. This book is suitable for a broad audience of mathematicians, mathematical physicists, and theoretical physicists and researchers in the field of Lie Theory.
410  0$aSpringer Proceedings in Mathematics & Statistics,$x2194-1009 ;$v111
606   $aGeometry
606   $aMathematical physics
606   $aTopological groups
606   $aLie groups
606   $aGeometry$3https://scigraph.springernature.com/ontologies/product-market-codes/M21006
606   $aMathematical Physics$3https://scigraph.springernature.com/ontologies/product-market-codes/M35000
606   $aTopological Groups, Lie Groups$3https://scigraph.springernature.com/ontologies/product-market-codes/M11132
615  0$aGeometry.
615  0$aMathematical physics.
615  0$aTopological groups.
615  0$aLie groups.
615 14$aGeometry.
615 24$aMathematical Physics.
615 24$aTopological Groups, Lie Groups.
676   $a510
676   $a512.55
676   $a512482
676   $a516
676   $a530.15
700   $aDobrev$b V. K.$0468747
702   $aDobrev$b Vladimir$4edt$4http://id.loc.gov/vocabulary/relators/edt
906   $aBOOK
912   $a9910299972203321
996   $aLie Theory and Its Applications in Physics$92881788
997   $aUNINA