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In set theory, an 'infinite set' is a set that is not a finite set. Infinite sets may be countable or uncountable. Some examples are:
★ the set of all integers, {..., -1, 0, 1, 2, ...}, is a countably infinite set; and
★ the set of all real numbers is an uncountably infinite set.
The set of natural numbers (whose existence is assured by the axiom of infinity) is infinite. It is the only set which is directly required by the axioms to be infinite. The existence of any other infinite set can be proved in ZFC only by showing that it follows from the existence of the natural numbers.
A set is infinite if and only if for every natural number the set has a subset whose cardinality is that natural number.
If the axiom of choice holds, then a set is infinite if and only if it includes a countable infinite subset.
If a set of sets is infinite or contains an infinite element, then its union is infinite. The powerset of an infinite set is infinite. Any superset of an infinite set is infinite. If an infinite set is partitioned into finitely many subsets, then at least one of them must be infinite. Any set which can be mapped onto an infinite set is infinite. The Cartesian product of an infinite set and a nonempty set is infinite. If the axiom of choice holds, the Cartesian product of an infinite number of sets each containing at least two elements is infinite.
If an infinite set is well-ordered, then it must have a nonempty subset which has no greatest element.
In ZF, a set is infinite if and only if the powerset of its powerset is a Dedekind-infinite set, having a proper subset equinumerous to itself. If the axiom of choice is also true, infinite sets are precisely the Dedekind-infinite sets.
If an infinite set is well-orderable, then it has many well-orderings which are non-isomorphic.
★ Infinity
★ Finite set
★ Aleph number
★ the set of all integers, {..., -1, 0, 1, 2, ...}, is a countably infinite set; and
★ the set of all real numbers is an uncountably infinite set.
| Contents |
| Properties |
| See also |
Properties
The set of natural numbers (whose existence is assured by the axiom of infinity) is infinite. It is the only set which is directly required by the axioms to be infinite. The existence of any other infinite set can be proved in ZFC only by showing that it follows from the existence of the natural numbers.
A set is infinite if and only if for every natural number the set has a subset whose cardinality is that natural number.
If the axiom of choice holds, then a set is infinite if and only if it includes a countable infinite subset.
If a set of sets is infinite or contains an infinite element, then its union is infinite. The powerset of an infinite set is infinite. Any superset of an infinite set is infinite. If an infinite set is partitioned into finitely many subsets, then at least one of them must be infinite. Any set which can be mapped onto an infinite set is infinite. The Cartesian product of an infinite set and a nonempty set is infinite. If the axiom of choice holds, the Cartesian product of an infinite number of sets each containing at least two elements is infinite.
If an infinite set is well-ordered, then it must have a nonempty subset which has no greatest element.
In ZF, a set is infinite if and only if the powerset of its powerset is a Dedekind-infinite set, having a proper subset equinumerous to itself. If the axiom of choice is also true, infinite sets are precisely the Dedekind-infinite sets.
If an infinite set is well-orderable, then it has many well-orderings which are non-isomorphic.
See also
★ Infinity
★ Finite set
★ Aleph number
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