Morley's categoricity theorem
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In model theory, a branch of mathematical logic, a theory is κ-categorical (or categorical in κ) if it has exactly one model of cardinality κ up to isomorphism. Morley's categoricity theorem is a theorem of Michael D. Morley which states that if a first-order theory in a countable language is categorical in some uncountable cardinality, then it is categorical in all uncountable cardinalities.
Saharon Shelah extended Morley's theorem to uncountable languages: if the language has cardinality κ and a theory is categorical in some uncountable cardinal greater than or equal to κ then it is categorical in all cardinalities greater than κ.
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[edit] History and motivation
Oswald Veblen in 1904 defined a theory to be categorical if all of its models are isomorphic. It follows from the definition above and the Löwenheim-Skolem theorem that any first-order theory with a model of infinite cardinality cannot be categorical. One is then immediately led to the more subtle notion of κ-categoricity, which asks: for which cardinals κ is there exactly one model of cardinality κ of the given theory T up to isomorphism? This is a deep question and significant progress was only made in 1954 when Jerzy Łoś noticed that, at least for complete theories T over countable languages with at least one infinite model, he could only find three ways for T to be κ-categorical at some κ:
- T is totally categorical, i.e. T is κ-categorical for all infinite cardinals κ.
- T is uncountably categorical, i.e. T is κ-categorical if and only if κ is an uncountable cardinal.
- T is countably categorical, i.e. T is κ-categorical if and only if κ is a countable cardinal.
In other words, he observed that, in all the cases he could think of, κ-categoricity at any one uncountable cardinal implied κ-categoricity at all other uncountable cardinals. This observation spurred a great amount of research into the 1960s, eventually culminating in Michael Morley's famous result that these are in fact the only possibilities. The theory was subsequently extended and refined by Saharon Shelah in the 1970s and beyond, leading to stability theory and Shelah's more general programme of classification theory.
[edit] Examples
There are not many natural examples of theories that are categorical in some uncountable cardinal. The known examples include:
- Pure identity theory (with no functions, constants, predicates other than "=", or axioms).
- The classic example is the theory of algebraically closed fields of a given characteristic: these are categorical for fields of size the continuum, and hence in all uncountable cardinalities. Categoricity does not say that all algebraically closed fields of characteristic 0 as large as the complex numbers C are the same as C; it only asserts that they are isomorphic as fields to C. It follows that although the completed p-adic closures Cp are all isomorphic as fields to C, they may (and in fact do) have completely different topological and analytic properties. The theory of algebraically closed fields of given characteristic is not categorical in ω (the countable infinite cardinal); there are models of transcendence degree 0, 1, 2, ..., ω.
- Vector spaces over a given countable field. This includes abelian groups of given prime exponent (essentially the same as vector spaces over a finite field) and divisible torsion-free abelian groups (essentially the same as vector spaces over the rationals).
- The theory of the set of natural numbers with a successor function.
There are also examples of theories that are categorical in ω but not categorical in uncountable cardinals. The simplest example is the theory of an equivalence relation with exactly two equivalence classes both of which are infinite. Another example is the theory of dense linear orders with no endpoints; Cantor proved that any such countable linear order is isomorphic to the rational numbers.
Any theory T categorical in some infinite cardinal κ is very close to being complete: all infinite models are equivalent to some model of cardinal α by the Löwenheim-Skolem theorem, and so are all equivalent as the theory is categorical in κ. So if we form a new theory T' by killing all finite models (add an axiom for each integer n stating that there exist at least n distinct elements) then all models of T' are equivalent so it is a complete theory, and has the same infinite models as T.
[edit] See also
[edit] References
- Chang, Chen Chung & Keisler, H. Jerome (1990), Model Theory, Studies in Logic and the Foundations of Mathematics, Elsevier, ISBN 978-0-444-88054-3
- Hodges, Wilfrid, "First-order Model Theory", The Stanford Encyclopedia of Philosophy (Summer 2005 Edition), Edward N. Zalta (ed.).
- Morley, Michael (1965), “Categoricity in Power”, Transactions of the American Mathematical Society 114 (2): 514–538, ISSN 0002-9947, DOI 10.2307/1994188
- Palyutin, E.A. (2001), “Categoricity in cardinality”, in Hazewinkel, Michiel, Encyclopaedia of Mathematics, Kluwer Academic Publishers, ISBN 978-1556080104
- Shelah, Saharon (1990), Classification theory and the number of nonisomorphic models (2nd ed.), Studies in Logic and the Foundations of Mathematics, Elsevier, ISBN 978-0-444-70260-9 (IX, 1.19, pg.49)
- Veblen, Oswald (1904), “A System of Axioms for Geometry”, Transactions of the American Mathematical Society 5 (3): 343–384, ISSN 0002-9947, DOI 10.2307/1986462