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Lie Models in Topology 2020 ed. [Kietas viršelis]

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  • Formatas: Hardback, 283 pages, aukštis x plotis: 235x155 mm, weight: 635 g, XXV, 283 p., 1 Hardback
  • Serija: Progress in Mathematics 335
  • Išleidimo metai: 16-Dec-2020
  • Leidėjas: Springer Nature Switzerland AG
  • ISBN-10: 303054429X
  • ISBN-13: 9783030544294
Kitos knygos pagal šią temą:
Lie Models in Topology 2020 ed.Didesnis paveikslėlis
  • Formatas: Hardback, 283 pages, aukštis x plotis: 235x155 mm, weight: 635 g, XXV, 283 p., 1 Hardback
  • Serija: Progress in Mathematics 335
  • Išleidimo metai: 16-Dec-2020
  • Leidėjas: Springer Nature Switzerland AG
  • ISBN-10: 303054429X
  • ISBN-13: 9783030544294
Kitos knygos pagal šią temą:
Pastovi nuoroda: https://www.kriso.lt/db/9783030544294.html
Raktažodžiai:

Since the birth of rational homotopy theory, the possibility of extending the Quillen approach –  in terms of Lie algebras – to a more general category of spaces, including the non-simply connected case, has been a challenge for the algebraic topologist community. Despite the clear Eckmann-Hilton duality between Quillen and Sullivan treatments, the simplicity in the realization of algebraic structures in the latter contrasts with the complexity required by the Lie algebra version.


In this book, the authors develop new tools to address these problems. Working with complete Lie algebras, they construct, in a combinatorial way, a cosimplicial Lie model for the standard simplices. This is a key object, which allows the definition of a new model and realization functors that turn out to be homotopically equivalent to the classical Quillen functors in the simply connected case. With this, the authors open new avenues for solving old problems and posing new questions.

This monograph is the winner of the 2020 Ferran Sunyer i Balaguer Prize, a prestigious award for books of expository nature presenting the latest developments in an active area of research in mathematics.


Recenzijos

This research monograph presents a major breakthrough by the authors in rational homotopy theory. Solving a hard classical problem, to be explained next, the book provides new tools and methods, and poses intriguing new questions. The major contribution is a new approach to the rational homotopy theory of arbitrary topological spaces and simplicial sets (not necessarily 1-connected, nilpotent, or even connected) by using complete differential graded Lie Q-algebras whose underlying complexes are potentially unbounded (cDGLs, henceforth). (José M. Moreno-Fernįndez, Mathematical Reviews, May, 2022)

The book is a timely and authoritative treatment of exciting breakthroughs and powerful techniques in homotopytheory. It will surely become a standard reference in the field. (Samuel Smith, zbMATH 1469.55001, 2021)



It is likely that modern topology graduate students have the background needed to appreciate the efficacy and sheer beauty of this whole approach to Lie models, so it would certainly be appropriate (and recommended!) for advanced courses and seminars. (John Oprea, MAA Reviews, July 18, 2021)

Introduction 1(17)
1 Background
1.1 Simplicial categories
18(7)
1.1.1 Simplicial sets
19(2)
1.1.2 Simplicial complexes
21(1)
1.1.3 Simplicial chains
22(3)
1.2 Differential categories
25(19)
1.2.1 Commutative differential graded algebras and the Sullivan model of a space
26(5)
1.2.2 Differential graded Lie algebras and the Quillen model of a space
31(3)
1.2.3 Differential graded coalgebras
34(3)
1.2.4 Differential graded Lie coalgebras
37(2)
1.2.5 A∞-algebras
39(5)
1.3 Model categories
44(10)
1.3.1 Differential model categories
48(2)
1.3.2 Cofibrantly generated model categories
50(4)
2 The Quillen Functors I, L and their Duals A, E
2.1 The functors L and L
54(7)
2.2 The functors A and E
61(11)
3 Complete Differential Graded Lie Algebras
3.1 Complete differential graded Lie algebras
72(4)
3.2 The completion of free Lie algebras
76(10)
3.3 Completion vs profinite completion
86(8)
4 Maurer--Cartan Elements and the Deligne Groupoid
4.1 Maurer--Cartan elements
94(2)
4.2 Exponential automorphisms and the Baker--Campbell--Hausdorff product
96(4)
4.3 The gauge action and the Deligne groupoid
100(7)
4.4 Applications to deformation theory
107(2)
4.5 The Goldman--Millson Theorem
109(9)
5 The Lawrence--Sullivan Interval
5.1 Introducing the Lawrence--Sullivan interval
118(3)
5.2 The LS interval as a cylinder
121(1)
5.3 The flow of a differential equation, the gauge action and the LS interval
122(3)
5.4 Subdivision of the LS interval and a model of the triangle
125(3)
5.5 Paths in a cdgl
128(2)
Bibliographical notes
130(2)
6 The Cosimplicial cdgl Σ•et;
6.1 The main result
132(2)
6.2 Inductive sequences of models of the standard simplices
134(10)
6.3 Sequences of equivariant models of the standard simplices
144(3)
6.4 The cosimplicial cdgl Σ•et;
147(1)
6.5 An explicit model for the tetrahedron
148(4)
6.6 Symmetric MC elements of simplicial complexes
152(9)
7 The Model and Realization Functors
7.1 Introducing the global model and realization functors. Adjointness
161(2)
7.2 First features of the global model and realization functors
163(4)
7.3 The path components and homotopy groups of (L)
167(5)
7.4 Homological behaviour of Σx
172(5)
7.5 The Deligne groupoid of the global model
177(7)
8 A Model Category for cdgl
8.1 The model category
184(5)
8.2 Weak equivalences and free extensions
189(4)
8.3 A path object, a cylinder object and homotopy of morphisms
193(6)
8.4 Minimal models of simplicial sets
199(3)
Bibliographical notes
202(2)
9 The Global Model Functor via Homotopy Transfer
9.1 The Dupont calculus on APL(Δ•et;)
204(4)
9.2 Obtaining Σ•et;, and Σx by transfer
208(3)
Bibliographical notes
211(3)
10 Extracting the Sullivan, Quillen and Neisendorfer Models from the Global Model
10.1 Connecting the global model with the Sullivan, Quillen and Neisendorfer models
214(3)
10.2 From the Lie minimal model to the Sullivan model and vice versa
217(3)
10.3 Coformal spaces
220(4)
11 The Deligne--Getzler--Hinich Functor MC•et; and Equivalence of Realizations
11.1 The set of Maurer--Cartan elements as a set of morphisms
224(4)
11.2 Simplicial contractions of APL(Δνllet;)
228(3)
11.3 The Deligne--Getzler--Hinich ∞-groupoid
231(6)
11.4 Equivalence of realizations and Bousfield--Kan completion
237(4)
Bibliographical notes
241(4)
12 Examples
12.1 Lie models of 2-dimensional complexes. Surfaces
245(8)
12.2 Lie models of tori and classifying spaces of right-angled Artin groups
253(2)
12.3 Lie model of a product
255(7)
12.4 Mapping spaces
262(13)
12.4.1 Lie models of mapping spaces
263(3)
12.4.2 Lie models of pointed mapping spaces
266(1)
12.4.3 Lie models of free loop spaces
267(2)
12.4.4 Simplicial enrichment of cdgl and cdga
269(2)
12.4.5 Complexes of derivations and homotopy groups of mapping spaces
271(4)
12.5 Homotopy invariants of the realization functor
275(6)
12.5.1 Action of π(L) on π*(L)
276(2)
12.5.2 The rational homotopy Lie algebra of (L)
278(2)
12.5.3 Postnikov decomposition of (L)
280(1)
Bibliographical notes
281(2)
Notation Index
General notation 283(3)
Categories 286(3)
Bibliography 289(8)
Index 297