In mathematical logic, Morley rank, introduced by , is a means of measuring the size of a subset of a model of a theory, generalizing the notion of dimension in algebraic geometry.

Definition

Fix a theory T with a model M. The Morley rank of a formula φ defining a definable (with parameters) subset S of M

is an ordinal or −1 or ∞, defined by first recursively defining what it means for a formula to have Morley rank at least α for some ordinal α.

  • The Morley rank is at least 0 if S is non-empty.
  • For α a successor ordinal, the Morley rank is at least α if in some elementary extension N of M, the set S has countably infinitely many disjoint definable subsets S<sub>i</sub>, each of rank at least α&nbsp;&minus;&nbsp;1.
  • For α a non-zero limit ordinal, the Morley rank is at least α if it is at least β for all β less than α.

The Morley rank is then defined to be α if it is at least α but not at least α&nbsp;+&nbsp;1, and is defined to be ∞ if it is at least α for all ordinals α, and is defined to be &minus;1 if S is empty.

For a definable subset of a model M (defined by a formula φ) the Morley rank is defined to be the Morley rank of φ in any ℵ<sub>0</sub>-saturated elementary extension of M. In particular for ℵ<sub>0</sub>-saturated models the Morley rank of a subset is the Morley rank of any formula defining the subset.

If φ defining S has rank α, and S breaks up into no more than n&nbsp;<&nbsp;ω subsets of rank α, then φ is said to have Morley degree&nbsp;n. A formula defining a finite set has Morley rank 0. A formula with Morley rank 1 and Morley degree 1 is called strongly minimal. A strongly minimal structure is one where the trivial formula x&nbsp;=&nbsp;x is strongly minimal. Morley rank and strongly minimal structures are key tools in the proof of Morley's categoricity theorem and in the larger area of model theoretic stability theory.

Examples

  • The empty set has Morley rank &minus;1, and conversely anything of Morley rank &minus;1 is empty.
  • A subset has Morley rank 0 if and only if it is finite and non-empty.
  • If V is an algebraic set in K<sup>n</sup>, for an algebraically closed field K, then the Morley rank of V is the same as its usual Krull dimension. The Morley degree of V is the number of irreducible components of maximal dimension; this is not the same as its degree in algebraic geometry, except when its components of maximal dimension are linear spaces.
  • The rational numbers, considered as an ordered set, has Morley rank ∞, as it contains a countable disjoint union of definable subsets isomorphic to itself.

See also

  • Cherlin–Zilber conjecture
  • Group of finite Morley rank
  • U-rank

References

  • Alexandre Borovik, Ali Nesin, "Groups of finite Morley rank", Oxford Univ. Press (1994)
  • B. Hart Stability theory and its variants (2000) pp.&nbsp;131–148 in Model theory, algebra and geometry, edited by D. Haskell et al., Math. Sci. Res. Inst. Publ. 39, Cambridge Univ. Press, New York, 2000. Contains a formal definition of Morley rank.
  • David Marker Model Theory of Differential Fields (2000) pp.&nbsp;53–63 in Model theory, algebra and geometry, edited by D. Haskell et al., Math. Sci. Res. Inst. Publ. 39, Cambridge Univ. Press, New York, 2000.