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On G-spaces, Serre classes and G-nilpotency

Published online by Cambridge University Press:  24 October 2008

Peter Hilton ,
Joseph Roitberg  and
David Singer
Peter Hilton
Affiliation:
Battelle Seattle Research Centre and Case Western Reserve University, Cleveland Hunter College and Graduate Centre of CUNY, New York, Case Western Reserve University, Cleveland
Joseph Roitberg
Affiliation:
Battelle Seattle Research Centre and Case Western Reserve University, Cleveland Hunter College and Graduate Centre of CUNY, New York, Case Western Reserve University, Cleveland
David Singer
Affiliation:
Battelle Seattle Research Centre and Case Western Reserve University, Cleveland Hunter College and Graduate Centre of CUNY, New York, Case Western Reserve University, Cleveland
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Extract

0. Introduction. The concept of a nilpotent action on a nilpotent group was studied in (2), and was crucial to the definition of a nilpotent map (or nilpotent fibration) in (4). These ideas had, of course, already been treated systematically in (1). The concept found a new, and related, application to homotopy theory in (3), where the following situation was studied. Let X be a nilpotent space and let G be a group which ‘acts’on X. Here it is not strictly speaking necessary to specify the nature of the action, provided that there is an induced action of G on the homotopy and homology groups of X. Thus G might be a group of base-point preserving homeomorphisms of X, or a group of (based) homotopy classes of self-homotopy-equivalences of X. We then discussed in (3) questions related to the nilpotency of the induced actions of G on the homotopy and homology groups of X and also relativized the theory to a discussion of fibrations on which the group G acts; to obtain interesting results related to nilpotency, it turned out to be at least necessary to suppose the fibration FEB quasinilpotent (7), meaning that all spaces are connected and π1B acts nilpotently on the homology groups of F.

Type
Research Article
Information
Mathematical Proceedings of the Cambridge Philosophical Society , Volume 84 , Issue 3 , November 1978 , pp. 443 - 454
Copyright
Copyright © Cambridge Philosophical Society 1978

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References

REFERENCES

(1)Bousfield, A. K. and Kan, D. M. Homotopy limits, completions and localizations. Lecture Notes in Math. no. 304, (Springer 1972).Google Scholar
(2)Hilton, P. Nilpotent actions on nilpotent groups. Lecture Notes in Math. no. 450, (Springer 1975), pp. 174196.Google Scholar
(3)Hilton, P.On G-spaces. Bol. Soc. Brasil Mat. 7 (1976), 6573.CrossRefGoogle Scholar
(4)Hilton, P., Mislin, G. and Roitberg, J.Localization of nilpotent groups and spaces (Mathematics Studies 15, North Holland, 1975).Google Scholar
(5)Hilton, P., Mislin, G., Roitberg, J. and Steiner, R. On free maps and free homotopies into nilpotent spaces. Proc. Vancouver Conference on Algebraic Topology (Springer Lecture Notes, to appear).Google Scholar
(6)Hilton, P. and Roitberg, J.Generalized C-theory and torsion phenomena in nilpotent spaces. Houston J. Math. 2 (1976), 525559.Google Scholar
(7)Hilton, P. and Roitberg, J.On the Zeeman comparison theorem for the homology of quasi-nilpotent fibrations. Quart. J. Math. Oxford Ser. (2) 27 (1976), 433444.Google Scholar
(8)Hilton, P. and Singer, D. On G-nilpotency (preprint).Google Scholar
(9)Robinson, D. J. S.A property of the lower central series of a group. Math. Z. 107 (1968), 225231.CrossRefGoogle Scholar
(10)Stammbach, U. Homology in group theory. Lecture Notes in Math. no. 359, (Springer 1973).Google Scholar