Transformation Groups Book contents
- Frontmatter
- Contents
- PREFACE
- PART ONE
- Generators and relations for groups of homeomorphisms
- Affine embeddings of real Lie groups
- Equivariant differential operators of a Lie group
- Equivariant regular neighbourhoods
- Characteristic numbers and equivariant spin cobordism
- Equivariant K-theory and cyclic subgroups
- ℤ/p manifolds with low dimensional fixed point set
- Gaps in the relative degree of symmetry
- Characters do not lie
- Actions of Z/2n on S3
- Periodic homeomorphisms on non-compact 3 manifolds
- Equivariant function spaces and equivariant stable homotopy theory
- A property of a characteristic class of an orbit foliation
- Orbit structure for Lie group actions on higher cohomology projective spaces
- On the existence of group actions on certain manifolds
- PART TWO (SUMMARIES AND SURVEYS)
Equivariant function spaces and equivariant stable homotopy theory
Published online by Cambridge University Press: 05 March 2012
- Frontmatter
- Contents
- PREFACE
- PART ONE
- Generators and relations for groups of homeomorphisms
- Affine embeddings of real Lie groups
- Equivariant differential operators of a Lie group
- Equivariant regular neighbourhoods
- Characteristic numbers and equivariant spin cobordism
- Equivariant K-theory and cyclic subgroups
- ℤ/p manifolds with low dimensional fixed point set
- Gaps in the relative degree of symmetry
- Characters do not lie
- Actions of Z/2n on S3
- Periodic homeomorphisms on non-compact 3 manifolds
- Equivariant function spaces and equivariant stable homotopy theory
- A property of a characteristic class of an orbit foliation
- Orbit structure for Lie group actions on higher cohomology projective spaces
- On the existence of group actions on certain manifolds
- PART TWO (SUMMARIES AND SURVEYS)
Summary
During the past six years relationships between spaces of equivariant self-maps of spheres and ordinary stable homotopy theory have been obtained by several different authors using somewhat different techniques [1, 2, 4, 6, 7, 9, 16]. Closer examination shows that such results fall into two classes: (i) Results relating equivariant stable homotopy theory to ordinary stable homotopy as in work of G. Segal, C. Kosniowski, T. tom Dieck; and H. Hauschild [4, 6, 7, 9, 16]. (ii) Results relating spaces of unpointed equivariant self-equivalences to homotopy theory as in the work of J. C. Becker and the author [1, 2].
This paper has two objectives. The first is to provide a natural relationship between the above classes of results, and the second is to apply this relationship to a question left open in [1, 2] - describing the composition product on the spaces FG studied in those papers and describing (in principle, at least) how the Pontrjagin ring structure on H⋆(FG) may be calculated. To be precise, we shall no use the homotopy equivalences constructed in [1, 2], but instead we shall replace them with more convenient maps defined in the same spirit.
It turns out that the systems studied in (i) and (ii) more or less fit together as halves of a larger object; this is developed in Section 1.
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- Transformation GroupsProceedings of the Conference in the University of Newcastle upon Tyne, August 1976, pp. 169 - 189Publisher: Cambridge University PressPrint publication year: 1977