The Disc Embedding Theorem
Herausgeber: Behrens, Stefan; Ray, Arunima; Powell, Mark; Kim, Min Hoon; Kalmar, Boldizsar
The Disc Embedding Theorem
Herausgeber: Behrens, Stefan; Ray, Arunima; Powell, Mark; Kim, Min Hoon; Kalmar, Boldizsar
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The Disc Embedding Theorem contains the first thorough and approachable exposition of Freedman's proof of the disc embedding theorem
The Disc Embedding Theorem contains the first thorough and approachable exposition of Freedman's proof of the disc embedding theorem
Produktdetails
- Produktdetails
- Verlag: Oxford University Press
- Seitenzahl: 496
- Erscheinungstermin: 25. Oktober 2021
- Englisch
- Abmessung: 168mm x 244mm x 30mm
- Gewicht: 950g
- ISBN-13: 9780198841319
- ISBN-10: 0198841310
- Artikelnr.: 61929849
- Verlag: Oxford University Press
- Seitenzahl: 496
- Erscheinungstermin: 25. Oktober 2021
- Englisch
- Abmessung: 168mm x 244mm x 30mm
- Gewicht: 950g
- ISBN-13: 9780198841319
- ISBN-10: 0198841310
- Artikelnr.: 61929849
Dr Stefan Behrens is an assistant professor in the Geometry and Topology group led by Prof. Dr. Stefan Bauer. His field of research is low dimensional topology, with a focus on the topology of smooth 4-manifolds. Boldizsar Kalmar was a research assistant at the Alfred Renyi Institute of Mathematics in 2005, then he got his PhD at Kyushu University in Japan in 2008. Then he did research at the Alfred Renyi Institute of Mathematics until 2017. He visited the Max Planck Institute for Mathematics in 2013. His research field is the topology of singular maps and low dimensional topology. Dr Mark Powell obtained his PhD from the University of Edinburgh under the supervision of Andrew Ranicki in 2011. After positions at Indiana University, the Max Planck Institute in Bonn, and at UQAM in Montreal, he moved to Durham University in 2017 to take up a position as Associate Professor. Dr Arunima Ray received a PhD in mathematics from Rice University, in Houston, USA in 2014 and subsequently held a postdoctoral fellowship at Brandeis University at Waltham, USA. She is currently a Lise Meitner group leader at the Max Planck Institute for Mathematics in Bonn, Germany. Her research is in low-dimensional topology, specifically the study of knots and links, and 3- and 4-manifolds.
* Preface
* 1: Context for the disc embedding theorem
* 2: Outline of the upcoming proof
* Part 1: Decomposition space theory
* 3: The Schoenflies theorem after Mazur, Morse, and Brown
* 4: Decomposition space theory and the Bing shrinking criterion
* 5: The Alexander gored ball and the Bing decomposition
* 6: A decomposition that does not shrink
* 7: The Whitehead decomposition
* 8: Mixed Bing-Whitehead decompositions
* 9: Shrinking starlike sets
* 10: The ball to ball theorem
* Part II: Building skyscrapers
* 11: Intersection numbers and the statement of the disc embedding
theorem
* 12: Gropes, towers, and skyscrapers
* 13: Picture camp
* 14: Architecture of infinite towers and skyscrapers
* 15: Basic geometric constructions
* 16: From immersed discs to capped gropes
* 17: Grope height raising and 1-storey capped towers
* 18: Tower height raising and embedding
* Part III: Interlude
* 19: Good groups
* 20: The s-cobordism theorem, the sphere embedding theorem, and the
Poincaré conjecture
* 21: The development of topological 4-manifold theory
* 22: Surgery theory and the classification of closed, simply connected
4-manifolds
* 23: Open problems
* Part IV: Skyscrapers are standard
* 24: Replicable rooms and boundary shrinkable skyscrapers
* 25: The collar adding lemma
* 26: Key facts about skyscrapers and decomposition space theory
* 27: Skyscrapers are standard: an overview
* 28: Skyscrapers are standard: the details
* Bibliography
* Afterword
* Index
* 1: Context for the disc embedding theorem
* 2: Outline of the upcoming proof
* Part 1: Decomposition space theory
* 3: The Schoenflies theorem after Mazur, Morse, and Brown
* 4: Decomposition space theory and the Bing shrinking criterion
* 5: The Alexander gored ball and the Bing decomposition
* 6: A decomposition that does not shrink
* 7: The Whitehead decomposition
* 8: Mixed Bing-Whitehead decompositions
* 9: Shrinking starlike sets
* 10: The ball to ball theorem
* Part II: Building skyscrapers
* 11: Intersection numbers and the statement of the disc embedding
theorem
* 12: Gropes, towers, and skyscrapers
* 13: Picture camp
* 14: Architecture of infinite towers and skyscrapers
* 15: Basic geometric constructions
* 16: From immersed discs to capped gropes
* 17: Grope height raising and 1-storey capped towers
* 18: Tower height raising and embedding
* Part III: Interlude
* 19: Good groups
* 20: The s-cobordism theorem, the sphere embedding theorem, and the
Poincaré conjecture
* 21: The development of topological 4-manifold theory
* 22: Surgery theory and the classification of closed, simply connected
4-manifolds
* 23: Open problems
* Part IV: Skyscrapers are standard
* 24: Replicable rooms and boundary shrinkable skyscrapers
* 25: The collar adding lemma
* 26: Key facts about skyscrapers and decomposition space theory
* 27: Skyscrapers are standard: an overview
* 28: Skyscrapers are standard: the details
* Bibliography
* Afterword
* Index
* Preface
* 1: Context for the disc embedding theorem
* 2: Outline of the upcoming proof
* Part 1: Decomposition space theory
* 3: The Schoenflies theorem after Mazur, Morse, and Brown
* 4: Decomposition space theory and the Bing shrinking criterion
* 5: The Alexander gored ball and the Bing decomposition
* 6: A decomposition that does not shrink
* 7: The Whitehead decomposition
* 8: Mixed Bing-Whitehead decompositions
* 9: Shrinking starlike sets
* 10: The ball to ball theorem
* Part II: Building skyscrapers
* 11: Intersection numbers and the statement of the disc embedding
theorem
* 12: Gropes, towers, and skyscrapers
* 13: Picture camp
* 14: Architecture of infinite towers and skyscrapers
* 15: Basic geometric constructions
* 16: From immersed discs to capped gropes
* 17: Grope height raising and 1-storey capped towers
* 18: Tower height raising and embedding
* Part III: Interlude
* 19: Good groups
* 20: The s-cobordism theorem, the sphere embedding theorem, and the
Poincaré conjecture
* 21: The development of topological 4-manifold theory
* 22: Surgery theory and the classification of closed, simply connected
4-manifolds
* 23: Open problems
* Part IV: Skyscrapers are standard
* 24: Replicable rooms and boundary shrinkable skyscrapers
* 25: The collar adding lemma
* 26: Key facts about skyscrapers and decomposition space theory
* 27: Skyscrapers are standard: an overview
* 28: Skyscrapers are standard: the details
* Bibliography
* Afterword
* Index
* 1: Context for the disc embedding theorem
* 2: Outline of the upcoming proof
* Part 1: Decomposition space theory
* 3: The Schoenflies theorem after Mazur, Morse, and Brown
* 4: Decomposition space theory and the Bing shrinking criterion
* 5: The Alexander gored ball and the Bing decomposition
* 6: A decomposition that does not shrink
* 7: The Whitehead decomposition
* 8: Mixed Bing-Whitehead decompositions
* 9: Shrinking starlike sets
* 10: The ball to ball theorem
* Part II: Building skyscrapers
* 11: Intersection numbers and the statement of the disc embedding
theorem
* 12: Gropes, towers, and skyscrapers
* 13: Picture camp
* 14: Architecture of infinite towers and skyscrapers
* 15: Basic geometric constructions
* 16: From immersed discs to capped gropes
* 17: Grope height raising and 1-storey capped towers
* 18: Tower height raising and embedding
* Part III: Interlude
* 19: Good groups
* 20: The s-cobordism theorem, the sphere embedding theorem, and the
Poincaré conjecture
* 21: The development of topological 4-manifold theory
* 22: Surgery theory and the classification of closed, simply connected
4-manifolds
* 23: Open problems
* Part IV: Skyscrapers are standard
* 24: Replicable rooms and boundary shrinkable skyscrapers
* 25: The collar adding lemma
* 26: Key facts about skyscrapers and decomposition space theory
* 27: Skyscrapers are standard: an overview
* 28: Skyscrapers are standard: the details
* Bibliography
* Afterword
* Index