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On large cardinals and partition relations

Published online by Cambridge University Press:  12 March 2014

E. M. Kleinberg  and
R. A. Shore
E. M. Kleinberg
Affiliation:
Massachusetts Institute of Technology, Cambridge, Massachusetts 02139
R. A. Shore
Affiliation:
Massachusetts Institute of Technology, Cambridge, Massachusetts 02139
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Extract

A significant portion of the study of large cardinals in set theory centers around the concept of “partition relation”. To best capture the basic idea here, we introduce the following notation: for x and y sets, κ an infinite cardinal, and γ an ordinal less than κ, we let [x]γ denote the collection of subsets of x of order-type γ and abbreviate with the partition relation for each function F frominto y there exists a subset C of κ of cardinality κ such that (such that for each α < γ) the range of F on [С]γ ([С]α) has cardinality 1. Now although each infinite cardinal κ satisfies the relation for each n and m in ω (F. P. Ramsey [8]), a connection with large cardinals arises when one asks, “For which uncountable κ do we have κ → (κ)2?” Indeed, any uncountable cardinal κ which satisfies κ → (κ)2 is strongly inaccessible and weakly compact (see [9]). As another example one can look at the improvements of Scott's original result to the effect that if there exists a measurable cardinal then there exists a nonconstructible set. Indeed, if κ is a measurable cardinal then κ → (κ)< ω, and as Solovay [11] has shown, if there exists a cardinal κ such that κ → (κ)< ω3 (κ → (1)< ω, even) then there exists a nonconstructible set of integers.

Type
Research Article
Information
The Journal of Symbolic Logic , Volume 36 , Issue 2 , June 1971 , pp. 305 - 308
Copyright
Copyright © Association for Symbolic Logic 1971

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References

[1]Erdös, P. and Hajnal, A., On the structure of set mappings, Acta Mathematica Academia Scientiarum Hungaricae, vol. 9 (1958), pp. 11131.CrossRefGoogle Scholar
[2]Erdös, P. and Rado, R., A partition calculus in set theory, Bulletin of the American Mathematical Society, vol. 62 (1956), pp. 427489.CrossRefGoogle Scholar
[3]Galvin, F., A generalization of Ramsey's theorem, Notices of the American Mathematical Society, vol. 14 (1967), p. 253.Google Scholar
[4]Galvin, F. and Prikry, K., to appear.Google Scholar
[5]Kleinberg, E. M., Strong partition properties for infinite cardinals, this Journal (to appear).Google Scholar
[6]Kleinberg, E. M., Somewhat homogeneous sets II, Notices of the American Mathematical Society, vol. 16 (1969), pp. 840, 1088, Abstract # 69T-E49, 69T-E89.Google Scholar
[7]Mathias, A. R. D., On a generalization of Ramsey's theorem, Notices of the American Mathematical Society, vol. 15 (1968), p. 931, Abstract #68T–E19.Google Scholar
[8]Ramsey, F. P., On a problem of formal logic, Proceedings of the London Mathematical Society, (2) vol. 30 (1930), pp. 264286.CrossRefGoogle Scholar
[9]Silver, J., Some applications of model theory in set theory, Doctoral dissertation, University of California (Berkeley), 1966.Google Scholar
[10]Silver, J., Every analytic set is Ramsey, this Journal, vol. 35. (1970), pp. 6064.Google Scholar
[11]Solovay, R. M., A nonconstructable set of integers, Transactions of the American Mathematical Society, vol. 127 (1967), pp. 5075.Google Scholar