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Grid Homology for Knots and Links [Kõva köide]

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  • Formaat: Hardback, 410 pages, kõrgus x laius: 254x178 mm
  • Sari: Mathematical Surveys and Monographs
  • Ilmumisaeg: 01-Oct-2015
  • Kirjastus: American Mathematical Society
  • ISBN-10: 1470417375
  • ISBN-13: 9781470417376
Teised raamatud teemal:
Grid Homology for Knots and LinksSuurem pilt
  • Formaat: Hardback, 410 pages, kõrgus x laius: 254x178 mm
  • Sari: Mathematical Surveys and Monographs
  • Ilmumisaeg: 01-Oct-2015
  • Kirjastus: American Mathematical Society
  • ISBN-10: 1470417375
  • ISBN-13: 9781470417376
Teised raamatud teemal:
Püsilink: https://www.kriso.ee/db/9781470417376.html
Märksõnad:
Knot theory is a classical area of low-dimensional topology, directly connected with the theory of three-manifolds and smooth four-manifold topology. In recent years, the subject has undergone transformative changes thanks to its connections with a number of other mathematical disciplines, including gauge theory; representation theory and categorification; contact geometry; and the theory of pseudo-holomorphic curves.

Starting from the combinatorial point of view on knots using their grid diagrams, this book serves as an introduction to knot theory, specifically as it relates to some of the above developments. After a brief overview of the background material in the subject, the book gives a self-contained treatment of knot Floer homology from the point of view of grid diagrams. Applications include computations of the unknotting number and slice genus of torus knots (asked first in the 1960s and settled in the 1990s), and tools to study variants of knot theory in the presence of a contact structure. Additional topics are presented to prepare readers for further study in holomorphic methods in low-dimensional topology, especially Heegaard Floer homology.

The book could serve as a textbook for an advanced undergraduate or part of a graduate course in knot theory. Standard background material is sketched in the text and the appendices.
Chapter 1 Introduction
1(12)
1.1 Grid homology and the Alexander polynomial
1(2)
1.2 Applications of grid homology
3(2)
1.3 Knot Floer homology
5(2)
1.4 Comparison with Khovanov homology
7(1)
1.5 On notational conventions
7(2)
1.6 Necessary background
9(1)
1.7 The organization of this book
9(2)
1.8 Acknowledgements
11(2)
Chapter 2 Knots and links in S3
13(30)
2.1 Knots and links
13(7)
2.2 Seifert surfaces
20(1)
2.3 Signature and the unknotting number
21(4)
2.4 The Alexander polynomial
25(5)
2.5 Further constructions of knots and links
30(2)
2.6 The slice genus
32(5)
2.7 The Goeritz matrix and the signature
37(6)
Chapter 3 Grid diagrams
43(22)
3.1 Planar grid diagrams
43(6)
3.2 Toroidal grid diagrams
49(2)
3.3 Grids and the Alexander polynomial
51(5)
3.4 Grid diagrams and Seifert surfaces
56(7)
3.5 Grid diagrams and the fundamental group
63(2)
Chapter 4 Grid homology
65(26)
4.1 Grid states
65(1)
4.2 Rectangles connecting grid states
66(2)
4.3 The bigrading on grid states
68(4)
4.4 The simplest version of grid homology
72(1)
4.5 Background on chain complexes
73(2)
4.6 The grid chain complex GC-
75(7)
4.7 The Alexander grading as a winding number
82(4)
4.8 Computations
86(4)
4.9 Further remarks
90(1)
Chapter 5 The invariance of grid homology
91(22)
5.1 Commutation invariance
91(8)
5.2 Stabilization invariance
99(8)
5.3 Completion of the invariance proof for grid homology
107(1)
5.4 The destabilization maps, revisited
108(2)
5.5 Other variants of the grid complex
110(1)
5.6 On the holomorphic theory
110(1)
5.7 Further remarks on stabilization maps
110(3)
Chapter 6 The unknotting number and τ
113(14)
6.1 The definition of τ and its unknotting estimate
113(2)
6.2 Construction of the crossing change maps
115(5)
6.3 The Milnor conjecture for torus knots
120(2)
6.4 Canonical grid cycles and estimates on τ
122(5)
Chapter 7 Basic properties of grid homology
127(8)
7.1 Symmetries of the simply blocked grid homology
127(2)
7.2 Genus bounds
129(1)
7.3 General properties of unblocked grid homology
130(2)
7.4 Symmetries of the unblocked theory
132(3)
Chapter 8 The slice genus and τ
135(16)
8.1 Slice genus bounds from τ and their consequences
135(1)
8.2 A version of grid homology for links
136(3)
8.3 Grid homology and saddle moves
139(4)
8.4 Adding unknots to a link
143(3)
8.5 Assembling the pieces: τ bounds the slice genus
146(1)
8.6 The existence of an exotic structure on R4
147(2)
8.7 Slice bounds vs. unknotting bounds
149(2)
Chapter 9 The oriented skein exact sequence
151(16)
9.1 The skein exact sequence
151(2)
9.2 The skein relation on the chain level
153(7)
9.3 Proofs of the skein exact sequences
160(2)
9.4 First computations using the skein sequence
162(1)
9.5 Knots with identical grid homologies
163(1)
9.6 The skein exact sequence and the crossing change map
164(2)
9.7 Further remarks
166(1)
Chapter 10 Grid homologies of alternating knots
167(20)
10.1 Properties of the determinant of a link
167(9)
10.2 The unoriented skein exact sequence
176(7)
10.3 Grid homology groups for alternating knots
183(2)
10.4 Further remarks
185(2)
Chapter 11 Grid homology for links
187(28)
11.1 The definition of grid homology for links
188(4)
11.2 The Alexander multi-grading on grid homology
192(2)
11.3 First examples
194(2)
11.4 Symmetries of grid homology for links
196(3)
11.5 The multi-variable Alexander polynomial
199(4)
11.6 The Euler characteristic of multi-graded grid homology
203(1)
11.7 Seifert genus bounds from grid homology for links
204(1)
11.8 Further examples
205(5)
11.9 Link polytopes and the Thurston norm
210(5)
Chapter 12 Invariants of Legendrian and transverse knots
215(32)
12.1 Legendrian knots in R3
216(4)
12.2 Grid diagrams for Legendrian knots
220(3)
12.3 Legendrian grid invariants
223(5)
12.4 Applications of the Legendrian invariants
228(3)
12.5 Transverse knots in R3
231(5)
12.6 Applications of the transverse invariant
236(4)
12.7 Invariants of Legendrian and transverse links
240(4)
12.8 Transverse knots, grid diagrams, and braids
244(1)
12.9 Further remarks
245(2)
Chapter 13 The filtered grid complex
247(26)
13.1 Some algebraic background
247(5)
13.2 Defining the invariant
252(2)
13.3 Topological invariance of the filtered quasi-isomorphism type
254(14)
13.4 Filtered homotopy equivalences
268(5)
Chapter 14 More on the filtered chain complex
273(18)
14.1 Information in the filtered grid complex
273(5)
14.2 Examples of filtered grid complexes
278(3)
14.3 Refining the Legendrian and transverse invariants: definitions
281(4)
14.4 Applications of the refined Legendrian and transverse invariants
285(2)
14.5 Filtrations in the case of links
287(2)
14.6 Remarks on three-manifold invariants
289(2)
Chapter 15 Grid homology over the integers
291(34)
15.1 Signs assignments and grid homology over Z
291(4)
15.2 Existence and uniqueness of sign assignments
295(7)
15.3 The invariance of grid homology over Z
302(6)
15.4 Invariance in the filtered theory
308(11)
15.5 Other grid homology constructions over Z
319(2)
15.6 On the τ-invariant
321(1)
15.7 Relations in the spin group
321(2)
15.8 Further remarks
323(2)
Chapter 16 The holomorphic theory
325(14)
16.1 Heegaard diagrams
325(2)
16.2 From Heegaard diagrams to holomorphic curves
327(6)
16.3 Multiple basepoints
333(2)
16.4 Equivalence of knot Floer homology with grid homology
335(3)
16.5 Further remarks
338(1)
Chapter 17 Open problems
339(8)
17.1 Open problems in grid homology
339(2)
17.2 Open problems in knot Floer homology
341(6)
Appendix A Homological algebra
347(20)
A.1 Chain complexes and their homology
347(3)
A.2 Exact sequences
350(2)
A.3 Mapping cones
352(5)
A.4 On the structure of homology
357(2)
A.5 Dual complexes
359(3)
A.6 On filtered complexes
362(1)
A.7 Small models for filtered grid complexes
363(2)
A.8 Filtered quasi-isomorphism versus filtered homotopy type
365(2)
Appendix B Basic theorems in knot theory
367(32)
B.1 The Reidemeister Theorem
367(6)
B.2 Reidemeister moves in contact knot theory
373(9)
B.3 The Reidemeister-Singer Theorem
382(5)
B.4 Cromwell's Theorem
387(7)
B.5 Normal forms of cobordisms between knots
394(5)
Bibliography 399(8)
Index 407
Peter S. Ozsvath, Princeton University, NJ, USA.

Andras I. Stipsicz, Renyi Institute of Mathematics, Budapest, Hungary.

Zoltan Szabo, Princeton University, NJ, USA.