Buch, Englisch, 143 Seiten, Format (B × H): 155 mm x 235 mm, Gewicht: 242 g
Buch, Englisch, 143 Seiten, Format (B × H): 155 mm x 235 mm, Gewicht: 242 g
Reihe: SpringerBriefs in Mathematical Physics
ISBN: 978-3-031-28153-2
Verlag: Springer
This open access book provides a detailed description of the geometric approach to the representation theory of the double affine Hecke algebra (DAHA) of rank one. Spherical DAHA is known to arise from the deformation quantization of the moduli space of SL(2,C) flat connections on the punctured torus. The authors demonstrate the study of the topological A-model on this moduli space and establish a correspondence between Lagrangian branes of the A-model and DAHA modules.
The finite-dimensional DAHA representations are shown to be in one-to-one correspondence with the compact Lagrangian branes. Along the way, the authors discover new finite-dimensional indecomposable representations. They proceed to embed the A-model story in an M-theory brane construction, closely related to the one used in the 3d/3d correspondence; as a result, modular tensor categories behind particular finite-dimensional representations with PSL(2,Z) action are identified. The relationship of Coulomb branch geometry and algebras of line operators in 4d N = 2* theories to the double affine Hecke algebra is studied further by using a further connection to the fivebrane system for the class S construction.
The book is targeted at experts in mathematical physics, representation theory, algebraic geometry, and string theory.
This is an open access book.
Zielgruppe
Research
Autoren/Hrsg.
Fachgebiete
Weitere Infos & Material
1 Introduction
1.1 Background
1.2 Results
1.3 Structure
2 2d sigma-models and DAHA
2.1 Higgs bundles and flat connections
2.2 DAHA of rank one and its spherical algebra
2.3 Canonical coisotropic branes in A-models2.3.1 Spherical DAHA as the algebra of (Bcc , Bcc )-strings
2.4 Lagrangian A-branes and modules of Oq(X)
2.5 (A, B, A)-branes for polynomial representations 22
2.6 Branes with compact supports and object matching 26
2.6.1 Generic fibers of the Hitchin fibration 27
2.6.2 Irreducible components in singular fibers of type I2 28
2.6.3 Moduli space of G-bundles 29
2.6.4 Exceptional divisors 31
2.7 Bound
2.7.1 At singular fiber of type I2 33
2.7.2 At global nilpotent cone of type I0* 35
3 3d theories and modularity 39
3.1 DAHA and modularity 39
3.1.1 SU(2): refined Chern-Simons and TQFT associated to Argyres-Douglas theory 43
3.1.2 SU(N): higher rank generalization 45
3.2 Relation to skein modules and MTC[M3] 47
4 4d theories, fivebranes, and M-theory 49
4.1 Coulomb branches of 4d N = 2* theories of rank one 50
4.2 Algebra of line operators 53
4.3 Including surface operator 57
A Glossary of symbols 62
B Basics of DAHA 63
B.1 DAHA
B.1.1 Double affine braid group and double affine Weyl group 64
B.1.2 PBW theorem for DAHA 64
B.1.3 Spherical subalgebra 65
B.1.4 Braid group and SL(2, Z) action 65
B.1.5 Polynomial representation of DAHA 66
B.1.6 Symmetric bilinear form 67
B.1.7 Degenerations 68
B.2 DAHA of type A1 70
B.2.1 Polynomial representation 70
B.2.2 Functional representation 72
B.2.3 Trigonometric Cherednik algebra of type A1 72
B.2.4 Rational Cherednik algebra of type A1 73
states of branes and short exact sequences: morphism matching 33
–i–
63
C Quantum torus algebra 73
C.1 Representations of quantum torus algebra 74
C.1.1 Unitary representations 75
C.1.2 Non-unitary representations 76
C.1.3 Geometric viewpoint 77C.2 Branes for quantum torus algebra 78
C.2.1 Cyclic representations 78
C.2.2 Polynomial representations 79
C.3 Symmetrized quantum torus 80
C.3.1 Representation theory 81
C.3.2 Corresponding branes 83
D 3d N = 4 theories and Cherednik algebras 84
D.1 Coulomb branches of 3d N = 4 theories 84
D.2 3d N = 4 Coulomb branches and Cherednik algebras 85
