set theory Set theory is the branch of mathematical logic that studies Set (mathematics), sets, which can be informally described as collections of objects. Although objects of any kind can be collected into a set, set theory – as a branch of mathema ...

, a limit ordinal is an

ordinal number In set theory, an ordinal number, or ordinal, is a generalization of ordinal numerals (first, second, th, etc.) aimed to extend enumeration to infinite sets. A finite set can be enumerated by successively labeling each element with the leas ...

that is neither zero nor a successor ordinal. Alternatively, an ordinal λ is a limit ordinal if there is an ordinal less than λ, and whenever β is an ordinal less than λ, then there exists an ordinal γ such that β < γ < λ. Every ordinal number is either zero, a successor ordinal, or a limit ordinal. For example, the smallest limit ordinal is ω, the smallest ordinal greater than every

natural number In mathematics, the natural numbers are the numbers 0, 1, 2, 3, and so on, possibly excluding 0. Some start counting with 0, defining the natural numbers as the non-negative integers , while others start with 1, defining them as the positive in ...

. This is a limit ordinal because for any smaller ordinal (i.e., for any natural number) ''n'' we can find another natural number larger than it (e.g. ''n''+1), but still less than ω. The next-smallest limit ordinal is ω+ω. This will be discussed further in the article. Using the von Neumann definition of ordinals, every ordinal is the well-ordered set of all smaller ordinals. The union of a nonempty set of ordinals that has no

greatest element In mathematics, especially in order theory, the greatest element of a subset S of a partially ordered set (poset) is an element of S that is greater than every other element of S. The term least element is defined duality (order theory), dually ...

is then always a limit ordinal. Using von Neumann cardinal assignment, every infinite

cardinal number In mathematics, a cardinal number, or cardinal for short, is what is commonly called the number of elements of a set. In the case of a finite set, its cardinal number, or cardinality is therefore a natural number. For dealing with the cas ...

is also a limit ordinal.

Alternative definitions

Various other ways to define limit ordinals are: *It is equal to the supremum of all the ordinals below it, but is not zero. (Compare with a successor ordinal: the set of ordinals below it has a maximum, so the supremum is this maximum, the previous ordinal.) *It is not zero and has no maximum element. *It can be written in the form ωα for α > 0. That is, in the Cantor normal form there is no finite number as last term, and the ordinal is nonzero. *It is a limit point of the class of ordinal numbers, with respect to the order topology. (The other ordinals are isolated points.) Some contention exists on whether or not 0 should be classified as a limit ordinal, as it does not have an immediate predecessor; some textbooks include 0 in the class of limit ordinals while others exclude it.for example, Kenneth Kunen, ''Set Theory. An introduction to independence proofs''. North-Holland.

Examples

Because the

class Class, Classes, or The Class may refer to: Common uses not otherwise categorized * Class (biology), a taxonomic rank * Class (knowledge representation), a collection of individuals or objects * Class (philosophy), an analytical concept used d ...

of ordinal numbers is

well-order In mathematics, a well-order (or well-ordering or well-order relation) on a set is a total ordering on with the property that every non-empty subset of has a least element in this ordering. The set together with the ordering is then calle ...

ed, there is a smallest infinite limit ordinal; denoted by ω (omega). The ordinal ω is also the smallest infinite ordinal (disregarding ''limit''), as it is the least upper bound of the

natural numbers In mathematics, the natural numbers are the numbers 0, 1, 2, 3, and so on, possibly excluding 0. Some start counting with 0, defining the natural numbers as the non-negative integers , while others start with 1, defining them as the positiv ...

. Hence ω represents the order type of the natural numbers. The next limit ordinal above the first is ω + ω = ω·2, which generalizes to ω·''n'' for any natural number ''n''. Taking the union (the supremum operation on any set of ordinals) of all the ω·n, we get ω·ω = ω², which generalizes to ω^''n'' for any natural number ''n''. This process can be further iterated as follows to produce: :

\omega^3, \omega^4, \ldots, \omega^\omega, \omega^, \ldots, \varepsilon_0 = \omega^, \ldots

In general, all of these recursive definitions via multiplication, exponentiation, repeated exponentiation, etc. yield limit ordinals. All of the ordinals discussed so far are still

countable In mathematics, a Set (mathematics), set is countable if either it is finite set, finite or it can be made in one to one correspondence with the set of natural numbers. Equivalently, a set is ''countable'' if there exists an injective function fro ...

ordinals. However, there is no recursively enumerable scheme for systematically naming all ordinals less than the Church–Kleene ordinal, which is a countable ordinal. Beyond the countable, the first uncountable ordinal is usually denoted ω₁. It is also a limit ordinal. Continuing, one can obtain the following (all of which are now increasing in cardinality): :

\omega_2, \omega_3, \ldots, \omega_\omega, \omega_, \ldots, \omega_,\ldots

In general, we always get a limit ordinal when taking the union of a nonempty set of ordinals that has no maximum element. The ordinals of the form ω²α, for α > 0, are limits of limits, etc.

Properties

The classes of successor ordinals and limit ordinals (of various cofinalities) as well as zero exhaust the entire class of ordinals, so these cases are often used in proofs by transfinite induction or definitions by transfinite recursion. Limit ordinals represent a sort of "turning point" in such procedures, in which one must use limiting operations such as taking the union over all preceding ordinals. In principle, one could do anything at limit ordinals, but taking the union is continuous in the order topology and this is usually desirable. If we use the von Neumann cardinal assignment, every infinite

is also a limit ordinal (and this is a fitting observation, as ''cardinal'' derives from the Latin ''cardo'' meaning ''hinge'' or ''turning point''): the proof of this fact is done by simply showing that every infinite successor ordinal is equinumerous to a limit ordinal via the Hotel Infinity argument. Cardinal numbers have their own notion of successorship and limit (everything getting upgraded to a higher level).

Indecomposable ordinals

Additively indecomposable A limit ordinal α is called additively indecomposable if it cannot be expressed as the sum of β < α ordinals less than α. These numbers are any ordinal of the form

\omega^\beta

for β an ordinal. The smallest is written

\gamma_0

, the second is written

\gamma_1

, etc. Multiplicatively indecomposable A limit ordinal α is called multiplicatively indecomposable if it cannot be expressed as the product of β < α ordinals less than α. These numbers are any ordinal of the form

\omega^

for β an ordinal. The smallest is written

\delta_0

, the second is written

\delta_1

, etc. Exponentially indecomposable and beyond The term "exponentially indecomposable" does not refer to ordinals not expressible as the exponential product ''(?)'' of β < α ordinals less than α, but rather the epsilon numbers, "tetrationally indecomposable" refers to the zeta numbers, "pentationally indecomposable" refers to the eta numbers, etc.

Alternative definitions

Examples

Properties

Indecomposable ordinals

See also

References

Further reading