Axiom of choice
In mathematics, the axiom of choice, or AC, is an axiom of set theory equivalent to the statement that the cartesian product of a collection of nonempty sets is nonempty. It states that for every indexed family of nonempty sets there exists an indexed family of elements such that for every . The axiom of choice was formulated in 1904 by Ernst Zermelo in order to formalize his proof of the wellordering theorem.^{1}
Informally put, the axiom of choice says that given any collection of bins, each containing at least one object, it is possible to make a selection of exactly one object from each bin. In many cases such a selection can be made without invoking the axiom of choice; this is in particular the case if the number of bins is finite, or if a selection rule is available: a distinguishing property that happens to hold for exactly one object in each bin. To give an informal example, for any (even infinite) collection of pairs of shoes, one can pick out the left shoe from each pair to obtain an appropriate selection, but for an infinite collection of pairs of socks (assumed to have no distinguishing features), such a selection can be obtained only by invoking the axiom of choice.
Although originally controversial, the axiom of choice is now used without reservation by most mathematicians,^{2} and it is included in Zermelo–Fraenkel set theory with the axiom of choice (ZFC), the standard form of axiomatic set theory. One motivation for this use is that a number of generally accepted mathematical results, such as Tychonoff's theorem, require the axiom of choice for their proofs. Contemporary set theorists also study axioms that are not compatible with the axiom of choice, such as the axiom of determinacy. The axiom of choice is avoided in some varieties of constructive mathematics, although there are varieties of constructive mathematics in which the axiom of choice is embraced.
Contents
Statement
A choice function is a function f, defined on a collection X of nonempty sets, such that for every set s in X, f(s) is an element of s. With this concept, the axiom can be stated:
 For any set X of nonempty sets, there exists a choice function f defined on X.
Formally, this may be expressed as follows:
Thus the negation of the axiom of choice states, there exists a set of nonempty sets that has no choice function.
Each choice function on a collection X of nonempty sets is an element of the Cartesian product of the sets in X. This is not the most general situation of a Cartesian product of a family of sets, where a same set can occur more than once as a factor; however, one can focus on elements of such a product that select the same element every time a given set appears as factor, and such elements correspond to an element of the Cartesian product of all distinct sets in the family. The axiom of choice asserts the existence of such elements; it is therefore equivalent to:
 Given any family of nonempty sets, their Cartesian product is a nonempty set.
Nomenclature ZF, AC, and ZFC
In this article and other discussions of the Axiom of Choice the following abbreviations are common:
 AC – the Axiom of Choice.
 ZF – Zermelo–Fraenkel set theory omitting the Axiom of Choice.
 ZFC – Zermelo–Fraenkel set theory, extended to include the Axiom of Choice.
Variants
There are many other equivalent statements of the axiom of choice. These are equivalent in the sense that, in the presence of other basic axioms of set theory, they imply the axiom of choice and are implied by it.
One variation avoids the use of choice functions by, in effect, replacing each choice function with its range.
 Given any set X of pairwise disjoint nonempty sets, there exists at least one set C that contains exactly one element in common with each of the sets in X.^{3}
This guarantees for any partition of a set X the existence of a subset C of X containing exactly one element from each part of the partition.
Another equivalent axiom only considers collections X that are essentially powersets of other sets:
 For any set A, the power set of A (with the empty set removed) has a choice function.
Authors who use this formulation often speak of the choice function on A, but be advised that this is a slightly different notion of choice function. Its domain is the powerset of A (with the empty set removed), and so makes sense for any set A, whereas with the definition used elsewhere in this article, the domain of a choice function on a collection of sets is that collection, and so only makes sense for sets of sets. With this alternate notion of choice function, the axiom of choice can be compactly stated as
 Every set has a choice function.^{4}
which is equivalent to
 For any set A there is a function f such that for any nonempty subset B of A, f(B) lies in B.
The negation of the axiom can thus be expressed as:
 There is a set A such that for all functions f (on the set of nonempty subsets of A), there is a B such that f(B) does not lie in B.
Restriction to finite sets
The statement of the axiom of choice does not specify whether the collection of nonempty sets is finite or infinite, and thus implies that every finite collection of nonempty sets has a choice function. However, that particular case is a theorem of Zermelo–Fraenkel set theory without the axiom of choice (ZF); it is easily proved by mathematical induction.^{5} In the even simpler case of a collection of one set, a choice function just corresponds to an element, so this instance of the axiom of choice says that every nonempty set has an element; this holds trivially. The axiom of choice can be seen as asserting the generalization of this property, already evident for finite collections, to arbitrary collections.
Usage
Until the late 19th century, the axiom of choice was often used implicitly, although it had not yet been formally stated. For example, after having established that the set X contains only nonempty sets, a mathematician might have said "let F(s) be one of the members of s for all s in X." In general, it is impossible to prove that F exists without the axiom of choice, but this seems to have gone unnoticed until Zermelo.
Not every situation requires the axiom of choice. For finite sets X, the axiom of choice follows from the other axioms of set theory. In that case it is equivalent to saying that if we have several (a finite number of) boxes, each containing at least one item, then we can choose exactly one item from each box. Clearly we can do this: We start at the first box, choose an item; go to the second box, choose an item; and so on. The number of boxes is finite, so eventually our choice procedure comes to an end. The result is an explicit choice function: a function that takes the first box to the first element we chose, the second box to the second element we chose, and so on. (A formal proof for all finite sets would use the principle of mathematical induction to prove "for every natural number k, every family of k nonempty sets has a choice function.") This method cannot, however, be used to show that every countable family of nonempty sets has a choice function, as is asserted by the axiom of countable choice. If the method is applied to an infinite sequence (X_{i} : i∈ω) of nonempty sets, a function is obtained at each finite stage, but there is no stage at which a choice function for the entire family is constructed, and no "limiting" choice function can be constructed, in general, in ZF without the axiom of choice.
Examples
The nature of the individual nonempty sets in the collection may make it possible to avoid the axiom of choice even for certain infinite collections. For example, suppose that each member of the collection X is a nonempty subset of the natural numbers. Every such subset has a smallest element, so to specify our choice function we can simply say that it maps each set to the least element of that set. This gives us a definite choice of an element from each set, and makes it unnecessary to apply the axiom of choice.
The difficulty appears when there is no natural choice of elements from each set. If we cannot make explicit choices, how do we know that our set exists? For example, suppose that X is the set of all nonempty subsets of the real numbers. First we might try to proceed as if X were finite. If we try to choose an element from each set, then, because X is infinite, our choice procedure will never come to an end, and consequently, we will never be able to produce a choice function for all of X. Next we might try specifying the least element from each set. But some subsets of the real numbers do not have least elements. For example, the open interval (0,1) does not have a least element: if x is in (0,1), then so is x/2, and x/2 is always strictly smaller than x. So this attempt also fails.
Additionally, consider for instance the unit circle S, and the action on S by a group G consisting of all rational rotations. Namely, these are rotations by angles which are rational multiples of π. Here G is countable while S is uncountable. Hence S breaks up into uncountably many orbits under G. Using the axiom of choice, we could pick a single point from each orbit, obtaining an uncountable subset X of S with the property that all of its translates by G are disjoint from X. The set of those translates partitions the circle into a countable collection of disjoint sets, which are all pairwise congruent. Since X is not measurable for any rotationinvariant countably additive finite measure on S, finding an algorithm to select a point in each orbit requires the axiom of choice. See nonmeasurable set for more details.
The reason that we are able to choose least elements from subsets of the natural numbers is the fact that the natural numbers are wellordered: every nonempty subset of the natural numbers has a unique least element under the natural ordering. One might say, "Even though the usual ordering of the real numbers does not work, it may be possible to find a different ordering of the real numbers which is a wellordering. Then our choice function can choose the least element of every set under our unusual ordering." The problem then becomes that of constructing a wellordering, which turns out to require the axiom of choice for its existence; every set can be wellordered if and only if the axiom of choice holds.
Criticism and acceptance
A proof requiring the axiom of choice may establish the existence of an object without explicitly defining the object in the language of set theory. For example, while the axiom of choice implies that there is a wellordering of the real numbers, there are models of set theory with the axiom of choice in which no wellordering of the reals is definable. Similarly, although a subset of the real numbers that is not Lebesgue measurable can be proven to exist using the axiom of choice, it is consistent that no such set is definable.
The axiom of choice produces these intangibles (objects that are proven to exist, but which cannot be explicitly constructed), which may conflict with some philosophical principles. Because there is no canonical wellordering of all sets, a construction that relies on a wellordering may not produce a canonical result, even if a canonical result is desired (as is often the case in category theory). This has been used as an argument against the use of the axiom of choice.
Another argument against the axiom of choice is that it implies the existence of counterintuitive objects. One example is the Banach–Tarski paradox which says that it is possible to decompose ("carve up") the 3dimensional solid unit ball into finitely many pieces and, using only rotations and translations, reassemble the pieces into two solid balls each with the same volume as the original. The pieces in this decomposition, constructed using the axiom of choice, are nonmeasurable sets.
Despite these facts, most mathematicians accept the axiom of choice as a valid principle for proving new results in mathematics. The debate is interesting enough, however, that it is considered of note when a theorem in ZFC (ZF plus AC) is logically equivalent (with just the ZF axioms) to the axiom of choice, and mathematicians look for results that require the axiom of choice to be false, though this type of deduction is less common than the type which requires the axiom of choice to be true.
It is possible to prove many theorems using neither the axiom of choice nor its negation; such statements will be true in any model of Zermelo–Fraenkel set theory (ZF), regardless of the truth or falsity of the axiom of choice in that particular model. The restriction to ZF renders any claim that relies on either the axiom of choice or its negation unprovable. For example, the Banach–Tarski paradox is neither provable nor disprovable from ZF alone: it is impossible to construct the required decomposition of the unit ball in ZF, but also impossible to prove there is no such decomposition. Similarly, all the statements listed below which require choice or some weaker version thereof for their proof are unprovable in ZF, but since each is provable in ZF plus the axiom of choice, there are models of ZF in which each statement is true. Statements such as the Banach–Tarski paradox can be rephrased as conditional statements, for example, "If AC holds, then the decomposition in the Banach–Tarski paradox exists." Such conditional statements are provable in ZF when the original statements are provable from ZF and the axiom of choice.
In constructive mathematics
As discussed above, in ZFC, the axiom of choice is able to provide "nonconstructive proofs" in which the existence of an object is proved although no explicit example is constructed. ZFC, however, is still formalized in classical logic. The axiom of choice has also been thoroughly studied in the context of constructive mathematics, where nonclassical logic is employed. The status of the axiom of choice varies between different varieties of constructive mathematics.
In MartinLöf type theory and higherorder Heyting arithmetic, the appropriate statement of the axiom of choice is (depending on approach) included as an axiom or provable as a theorem.^{6} Errett Bishop argued that the axiom of choice was constructively acceptable, saying
 "A choice function exists in constructive mathematics, because a choice is implied by the very meaning of existence."^{7}
In constructive set theory, however, Diaconescu's theorem shows that the axiom of choice implies the Law of excluded middle (unlike in MartinLöf type theory, where it does not). Thus the axiom of choice is not generally available in constructive set theory. A cause for this difference is that the axiom of choice in type theory does not have the extensionality properties that the axiom of choice in constructive set theory does.^{8}
Some results in constructive set theory use the axiom of countable choice or the axiom of dependent choice, which do not imply the law of the excluded middle in constructive set theory. Although the axiom of countable choice in particular is commonly used in constructive mathematics, its use has also been questioned.^{9}
Independence
Assuming ZF is consistent, Kurt Gödel showed that the negation of the axiom of choice is not a theorem of ZF by constructing an inner model (the constructible universe) which satisfies ZFC and thus showing that ZFC is consistent. Assuming ZF is consistent, Paul Cohen employed the technique of forcing, developed for this purpose, to show that the axiom of choice itself is not a theorem of ZF by constructing a much more complex model which satisfies ZF¬C (ZF with the negation of AC added as axiom) and thus showing that ZF¬C is consistent. Together these results establish that the axiom of choice is logically independent of ZF. The assumption that ZF is consistent is harmless because adding another axiom to an already inconsistent system cannot make the situation worse. Because of independence, the decision whether to use the axiom of choice (or its negation) in a proof cannot be made by appeal to other axioms of set theory. The decision must be made on other grounds.
One argument given in favor of using the axiom of choice is that it is convenient to use it because it allows one to prove some simplifying propositions that otherwise could not be proved. Many theorems which are provable using choice are of an elegant general character: every ideal in a ring is contained in a maximal ideal, every vector space has a basis, and every product of compact spaces is compact. Without the axiom of choice, these theorems may not hold for mathematical objects of large cardinality.
The proof of the independence result also shows that a wide class of mathematical statements, including all statements that can be phrased in the language of Peano arithmetic, are provable in ZF if and only if they are provable in ZFC.^{10} Statements in this class include the statement that P = NP, the Riemann hypothesis, and many other unsolved mathematical problems. When one attempts to solve problems in this class, it makes no difference whether ZF or ZFC is employed if the only question is the existence of a proof. It is possible, however, that there is a shorter proof of a theorem from ZFC than from ZF.
The axiom of choice is not the only significant statement which is independent of ZF. For example, the generalized continuum hypothesis (GCH) is not only independent of ZF, but also independent of ZFC. However, ZF plus GCH implies AC, making GCH a strictly stronger claim than AC, even though they are both independent of ZF.
Stronger axioms
The axiom of constructibility and the generalized continuum hypothesis each imply the axiom of choice and so are strictly stronger than it. In class theories such as Von Neumann–Bernays–Gödel set theory and Morse–Kelley set theory, there is a possible axiom called the axiom of global choice which is stronger than the axiom of choice for sets because it also applies to proper classes. And the axiom of global choice follows from the axiom of limitation of size.
Equivalents
There are important statements that, assuming the axioms of ZF but neither AC nor ¬AC, are equivalent to the axiom of choice. The most important among them are Zorn's lemma and the wellordering theorem. In fact, Zermelo initially introduced the axiom of choice in order to formalize his proof of the wellordering theorem.
 Set theory
 Wellordering theorem: Every set can be wellordered. Consequently, every cardinal has an initial ordinal.
 Tarski's theorem: For every infinite set A, there is a bijective map between the sets A and A×A.
 Trichotomy: If two sets are given, then either they have the same cardinality, or one has a smaller cardinality than the other.
 The Cartesian product of any family of nonempty sets is nonempty.
 König's theorem: Colloquially, the sum of a sequence of cardinals is strictly less than the product of a sequence of larger cardinals. (The reason for the term "colloquially" is that the sum or product of a "sequence" of cardinals cannot be defined without some aspect of the axiom of choice.)
 Every surjective function has a right inverse.
 Order theory
 Zorn's lemma: Every nonempty partially ordered set in which every chain (i.e. totally ordered subset) has an upper bound contains at least one maximal element.
 Hausdorff maximal principle: In any partially ordered set, every totally ordered subset is contained in a maximal totally ordered subset. The restricted principle "Every partially ordered set has a maximal totally ordered subset" is also equivalent to AC over ZF.
 Tukey's lemma: Every nonempty collection of finite character has a maximal element with respect to inclusion.
 Antichain principle: Every partially ordered set has a maximal antichain.
 Abstract algebra
 Every vector space has a basis.^{11}
 Every unital ring other than the trivial ring contains a maximal ideal.
 For every nonempty set S there is a binary operation defined on S that gives it a group structure.^{12} (A cancellative binary operation is enough.)
 Functional analysis
 The closed unit ball of the dual of a normed vector space over the reals has an extreme point.
 Pointset topology
 Tychonoff's theorem: Every product of compact topological spaces is compact.
 In the product topology, the closure of a product of subsets is equal to the product of the closures.
 Mathematical logic
 If S is a set of sentences of firstorder logic and B is a consistent subset of S, then B is included in a set that is maximal among consistent subsets of S. The special case where S is the set of all firstorder sentences in a given signature is weaker, equivalent to the Boolean prime ideal theorem; see the section "Weaker forms" below.
 Graph theory
 Every connected graph has a spanning tree.^{13}
Category theory
There are several results in category theory which invoke the axiom of choice for their proof. These results might be weaker than, equivalent to, or stronger than the axiom of choice, depending on the strength of the technical foundations. For example, if one defines categories in terms of sets, that is, as sets of objects and morphisms (usually called a small category), or even locally small categories, whose homobjects are sets, then there is no category of all sets, and so it is difficult for a categorytheoretic formulation to apply to all sets. On the other hand, other foundational descriptions of category theory are considerably stronger, and an identical categorytheoretic statement of choice may be stronger than the standard formulation, à la class theory, mentioned above.
Examples of categorytheoretic statements which require choice include:
 Every small category has a skeleton.
 If two small categories are weakly equivalent, then they are equivalent.
 Every continuous functor on a smallcomplete category which satisfies the appropriate solution set condition has a leftadjoint (the Freyd adjoint functor theorem).
Weaker forms
There are several weaker statements that are not equivalent to the axiom of choice, but are closely related. One example is the axiom of dependent choice (DC). A still weaker example is the axiom of countable choice (AC_{ω} or CC), which states that a choice function exists for any countable set of nonempty sets. These axioms are sufficient for many proofs in elementary mathematical analysis, and are consistent with some principles, such as the Lebesgue measurability of all sets of reals, that are disprovable from the full axiom of choice.
Other choice axioms weaker than axiom of choice include the Boolean prime ideal theorem and the axiom of uniformization. The former is equivalent in ZF to the existence of an ultrafilter containing each given filter, proved by Tarski in 1930.
Results requiring AC (or weaker forms) but weaker than it
One of the most interesting aspects of the axiom of choice is the large number of places in mathematics that it shows up. Here are some statements that require the axiom of choice in the sense that they are not provable from ZF but are provable from ZFC (ZF plus AC). Equivalently, these statements are true in all models of ZFC but false in some models of ZF.
 Set theory
 Any union of countably many countable sets is itself countable.
 If the set A is infinite, then there exists an injection from the natural numbers N to A (see Dedekind infinite).
 Every infinite game in which is a Borel subset of Baire space is determined.
 Measure theory
 The Vitali theorem on the existence of nonmeasurable sets which states that there is a subset of the real numbers that is not Lebesgue measurable.
 The Hausdorff paradox.
 The Banach–Tarski paradox.
 The Lebesgue measure of a countable disjoint union of measurable sets is equal to the sum of the measures of the individual sets.
 Algebra
 Every field has an algebraic closure.
 Every field extension has a transcendence basis.
 Stone's representation theorem for Boolean algebras needs the Boolean prime ideal theorem.
 The Nielsen–Schreier theorem, that every subgroup of a free group is free.
 The additive groups of R and C are isomorphic.^{14}^{15}
 Functional analysis
 The Hahn–Banach theorem in functional analysis, allowing the extension of linear functionals
 The theorem that every Hilbert space has an orthonormal basis.
 The Banach–Alaoglu theorem about compactness of sets of functionals.
 The Baire category theorem about complete metric spaces, and its consequences, such as the open mapping theorem and the closed graph theorem.
 On every infinitedimensional topological vector space there is a discontinuous linear map.
 General topology
 A uniform space is compact if and only if it is complete and totally bounded.
 Every Tychonoff space has a Stone–Čech compactification.
 Mathematical logic
 Gödel's completeness theorem for firstorder logic: every consistent set of firstorder sentences has a completion. That is, every consistent set of firstorder sentences can be extended to a maximal consistent set.
Stronger forms of the negation of AC
Now, consider stronger forms of the negation of AC. For example, if we abbreviate by BP the claim that every set of real numbers has the property of Baire, then BP is stronger than ¬AC, which asserts the nonexistence of any choice function on perhaps only a single set of nonempty sets. Note that strengthened negations may be compatible with weakened forms of AC. For example, ZF + DC^{16} + BP is consistent, if ZF is.
It is also consistent with ZF + DC that every set of reals is Lebesgue measurable; however, this consistency result, due to Robert M. Solovay, cannot be proved in ZFC itself, but requires a mild large cardinal assumption (the existence of an inaccessible cardinal). The much stronger axiom of determinacy, or AD, implies that every set of reals is Lebesgue measurable, has the property of Baire, and has the perfect set property (all three of these results are refuted by AC itself). ZF + DC + AD is consistent provided that a sufficiently strong large cardinal axiom is consistent (the existence of infinitely many Woodin cardinals).
Statements consistent with the negation of AC
There are models of ZermeloFraenkel set theory in which the axiom of choice is false. We will abbreviate "ZermeloFraenkel set theory plus the negation of the axiom of choice" by ZF¬C. For certain models of ZF¬C, it is possible to prove the negation of some standard facts. Note that any model of ZF¬C is also a model of ZF, so for each of the following statements, there exists a model of ZF in which that statement is true.
 There exists a model of ZF¬C in which there is a function f from the real numbers to the real numbers such that f is not continuous at a, but f is sequentially continuous at a, i.e., for any sequence {x_{n}} converging to a, lim_{n} f(x_{n})=f(a).
 There exists a model of ZF¬C which has an infinite set of real numbers without a countably infinite subset.
 There exists a model of ZF¬C in which real numbers are a countable union of countable sets.^{17}
 There exists a model of ZF¬C in which there is a field with no algebraic closure.
 In all models of ZF¬C there is a vector space with no basis.
 There exists a model of ZF¬C in which there is a vector space with two bases of different cardinalities.
 There exists a model of ZF¬C in which there is a free complete boolean algebra on countably many generators.^{18}
For proofs, see Thomas Jech, The Axiom of Choice, American Elsevier Pub. Co., New York, 1973.
 There exists a model of ZF¬C in which every set in R^{n} is measurable. Thus it is possible to exclude counterintuitive results like the Banach–Tarski paradox which are provable in ZFC. Furthermore, this is possible whilst assuming the Axiom of dependent choice, which is weaker than AC but sufficient to develop most of real analysis.
 In all models of ZF¬C, the generalized continuum hypothesis does not hold.
Quotes
"The Axiom of Choice is obviously true, the wellordering principle obviously false, and who can tell about Zorn's lemma?" — Jerry Bona
 This is a joke: although the three are all mathematically equivalent, many mathematicians find the axiom of choice to be intuitive, the wellordering principle to be counterintuitive, and Zorn's lemma to be too complex for any intuition.
"The Axiom of Choice is necessary to select a set from an infinite number of socks, but not an infinite number of shoes." — Bertrand Russell
 The observation here is that one can define a function to select from an infinite number of pairs of shoes by stating for example, to choose the left shoe. Without the axiom of choice, one cannot assert that such a function exists for pairs of socks, because left and right socks are (presumably) indistinguishable from each other.
"Tarski tried to publish his theorem [the equivalence between AC and 'every infinite set A has the same cardinality as AxA', see above] in Comptes Rendus, but Fréchet and Lebesgue refused to present it. Fréchet wrote that an implication between two well known [true] propositions is not a new result, and Lebesgue wrote that an implication between two false propositions is of no interest".
 PolishAmerican mathematician Jan Mycielski relates this anecdote in a 2006 article in the Notices of the AMS.
"The axiom gets its name not because mathematicians prefer it to other axioms." — A. K. Dewdney
 This quote comes from the famous April Fools' Day article in the computer recreations column of the Scientific American, April 1989.
Notes
 ^ Zermelo, Ernst (1904). "Beweis, dass jede Menge wohlgeordnet werden kann" (reprint). Mathematische Annalen 59 (4): 514–16. doi:10.1007/BF01445300.
 ^ Jech, 1977, p. 348ff; MartinLöf 2008, p. 210.
 ^ Herrlich, p. 9.
 ^ Patrick Suppes, "Axiomatic Set Theory", Dover, 1972 (1960), ISBN 0486616304, p. 240
 ^ Tourlakis (2003), pp. 209–210, 215–216.
 ^ Per MartinLöf, Intuitionistic type theory, 1980. Anne Sjerp Troelstra, Metamathematical investigation of intuitionistic arithmetic and analysis, Springer, 1973.
 ^ Errett Bishop and Douglas S. Bridges, Constructive analysis, SpringerVerlag, 1985.
 ^ Per MartinLöf, "100 Years of Zermelo’s Axiom of Choice: What was the Problem with It?", The Computer Journal (2006) 49 (3): 345350. doi: 10.1093/comjnl/bxh162
 ^ Fred Richman, “Constructive mathematics without choice”, in: Reuniting the Antipodes—Constructive and Nonstandard Views of the Continuum (P. Schuster et al., eds), Synthèse Library 306, 199–205, Kluwer Academic Publishers, Amsterdam, 2001.
 ^ This is because arithmetical statements are absolute to the constructible universe L. Shoenfield's absoluteness theorem gives a more general result.
 ^ Blass, Andreas (1984). "Existence of bases implies the axiom of choice". Contemporary mathematics 31.
 ^ A. Hajnal, A. Kertész: Some new algebraic equivalents of the axiom of choice, Publ. Math. Debrecen, 19(1972), 339–340, see also H. Rubin, J. Rubin, Equivalents of the axiom of choice, II, NorthHolland, 1985, p. 111.
 ^ Serre, JeanPierre (2003), Trees, Springer Monographs in Mathematics, Springer, p. 23; Soukup, Lajos (2008), "Infinite combinatorics: from finite to infinite", Horizons of combinatorics, Bolyai Soc. Math. Stud. 17, Berlin: Springer, pp. 189–213, doi:10.1007/9783540772002_10, MR 2432534. See in particular Theorem 2.1, pp. 192–193.
 ^ http://www.cs.nyu.edu/pipermail/fom/2006February/009959.html
 ^ http://journals.cambridge.org/action/displayFulltext?type=1&fid=4931240&aid=4931232
 ^ Axiom of dependent choice
 ^ Jech, Thomas (1973) "The axiom of choice", ISBN 0444104844, CH. 10, p. 142.
 ^ Stavi, Jonathan (1974). "A model of ZF with an infinite free complete Boolean algebra" (reprint). Israel Journal of Mathematics 20 (2): 149–163. doi:10.1007/BF02757883.
References
 Horst Herrlich, Axiom of Choice, Springer Lecture Notes in Mathematics 1876, Springer Verlag Berlin Heidelberg (2006). ISBN 3540309896.
 Paul Howard and Jean Rubin, "Consequences of the Axiom of Choice". Mathematical Surveys and Monographs 59; American Mathematical Society; 1998.
 Thomas Jech, "About the Axiom of Choice." Handbook of Mathematical Logic, John Barwise, ed., 1977.
 Per MartinLöf, "100 years of Zermelo's axiom of choice: What was the problem with it?", in Logicism, Intuitionism, and Formalism: What Has Become of Them?, Sten Lindström, Erik Palmgren, Krister Segerberg, and Viggo StoltenbergHansen, editors (2008). ISBN 1402089252
 Gregory H Moore, "Zermelo's axiom of choice, Its origins, development and influence", Springer; 1982. ISBN 0387906703, available as a Dover Publications reprint, 2013, ISBN 0486488411.
 Herman Rubin, Jean E. Rubin: Equivalents of the axiom of choice. North Holland, 1963. Reissued by Elsevier, April 1970. ISBN 0720422256.
 Herman Rubin, Jean E. Rubin: Equivalents of the Axiom of Choice II. North Holland/Elsevier, July 1985, ISBN 0444877088.
 George Tourlakis, Lectures in Logic and Set Theory. Vol. II: Set Theory, Cambridge University Press, 2003. ISBN 0511066597
 Ernst Zermelo, "Untersuchungen über die Grundlagen der Mengenlehre I," Mathematische Annalen 65: (1908) pp. 261–81. PDF download via digizeitschriften.de

 Translated in: Jean van Heijenoort, 2002. From Frege to Gödel: A Source Book in Mathematical Logic, 18791931. New edition. Harvard University Press. ISBN 0674324498
 1904. "Proof that every set can be wellordered," 13941.
 1908. "Investigations in the foundations of set theory I," 199215.
 Translated in: Jean van Heijenoort, 2002. From Frege to Gödel: A Source Book in Mathematical Logic, 18791931. New edition. Harvard University Press. ISBN 0674324498
External links
 Hazewinkel, Michiel, ed. (2001), "Axiom of choice", Encyclopedia of Mathematics, Springer, ISBN 9781556080104
 Axiom of Choice and Its Equivalents at ProvenMath includes formal statement of the Axiom of Choice, Hausdorff's Maximal Principle, Zorn's Lemma and formal proofs of their equivalence down to the finest detail.
 Consequences of the Axiom of Choice, based on the book by Paul Howard and Jean Rubin.
 The Axiom of Choice entry by John Lane Bell in the Stanford Encyclopedia of Philosophy

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