In the mathematical discipline of

set theory Set theory is the branch of mathematical logic that studies 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 mathematics, is mostly conce ...

, 0^# (zero sharp, also 0#) is the set of true

formulae In science, a formula is a concise way of expressing information symbolically, as in a mathematical formula or a ''chemical formula''. The informal use of the term ''formula'' in science refers to the general construct of a relationship betwee ...

about indiscernibles and order-indiscernibles in the

Gödel constructible universe In mathematics, in set theory, the constructible universe (or Gödel's constructible universe), denoted by , is a particular class of sets that can be described entirely in terms of simpler sets. is the union of the constructible hierarchy . It ...

. It is often encoded as a subset of the integers (using

Gödel numbering In mathematical logic, a Gödel numbering is a function that assigns to each symbol and well-formed formula of some formal language a unique natural number, called its Gödel number. The concept was developed by Kurt Gödel for the proof of his ...

), or as a subset of the

hereditarily finite set In mathematics and set theory, hereditarily finite sets are defined as finite sets whose elements are all hereditarily finite sets. In other words, the set itself is finite, and all of its elements are finite sets, recursively all the way down to t ...

s, or as a

real number In mathematics, a real number is a number that can be used to measure a ''continuous'' one-dimensional quantity such as a distance, duration or temperature. Here, ''continuous'' means that values can have arbitrarily small variations. Every real ...

. Its existence is unprovable in ZFC, the standard form of

axiomatic 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 mathematics, ...

, but follows from a suitable

large cardinal In the mathematical field of set theory, a large cardinal property is a certain kind of property of transfinite cardinal numbers. Cardinals with such properties are, as the name suggests, generally very "large" (for example, bigger than the least � ...

axiom. It was first introduced as a set of formulae in Silver's 1966 thesis, later published as , where it was denoted by Σ, and rediscovered by , who considered it as a subset of the natural numbers and introduced the notation O^# (with a capital letter O; this later changed to the numeral '0'). Roughly speaking, if 0^# exists then the universe ''V'' of sets is much larger than the universe ''L'' of constructible sets, while if it does not exist then the universe of all sets is closely approximated by the constructible sets.

Definition

Zero sharp was defined by Silver and Solovay as follows. Consider the language of set theory with extra constant symbols ''c''₁, ''c''₂, ... for each positive integer. Then 0^# is defined to be the set of Gödel numbers of the true sentences about the constructible universe, with ''c''_''i'' interpreted as the uncountable cardinal ℵ_''i''. (Here ℵ_''i'' means ℵ_''i'' in the full universe, not the constructible universe.) If there is in ''V'' an uncountable set of Silver order- indiscernibles in the constructible universe ''L'', then 0^# is the set of Gödel numbers of formulas θ of set theory such that :

L_ \models \theta (\omega_1, \omega_2, ... \omega_n)

where ω₁, ... ω_ω are the "small" uncountable initial ordinals in ''V'', but have all large cardinal properties consistent with ''V''=''L'' relative to ''L''. There is a subtlety about this definition: by

Tarski's undefinability theorem Tarski's undefinability theorem, stated and proved by Alfred Tarski in 1933, is an important limitative result in mathematical logic, the foundations of mathematics, and in formal semantics. Informally, the theorem states that ''arithmetical truth ...

it is not, in general, possible to define the truth of a formula of set theory in the language of set theory. To solve this, Silver and Solovay assumed the existence of a suitable large cardinal, such as a

Ramsey cardinal In mathematics, a Ramsey cardinal is a certain kind of large cardinal number introduced by and named after Frank P. Ramsey, whose theorem establishes that ω enjoys a certain property that Ramsey cardinals generalize to the uncountable case. Let ...

, and showed that with this extra assumption it is possible to define the truth of statements about the constructible universe. More generally, the definition of 0^# works provided that there is an uncountable set of indiscernibles for some ''L''_α, and the phrase "0^# exists" is used as a shorthand way of saying this. There are several minor variations of the definition of 0^#, which make no significant difference to its properties. There are many different choices of Gödel numbering, and 0^# depends on this choice. Instead of being considered as a subset of the natural numbers, it is also possible to encode 0^# as a subset of formulae of a language, or as a subset of the hereditarily finite sets, or as a real number.

Statements implying existence

The condition about the existence of a Ramsey cardinal implying that 0^# exists can be weakened. The existence of ω₁-

Erdős cardinal In mathematics, an Erdős cardinal, also called a partition cardinal is a certain kind of large cardinal number introduced by . The Erdős cardinal is defined to be the least cardinal such that for every function there is a set of order type tha ...

s implies the existence of 0^#. This is close to being best possible, because the existence of 0^# implies that in the constructible universe there is an α-Erdős cardinal for all countable α, so such cardinals cannot be used to prove the existence of 0^#.

Chang's conjecture In model theory, a branch of mathematical logic, Chang's conjecture, attributed to Chen Chung Chang by , states that every model of type (ω2,ω1) for a countable language has an elementary submodel of type (ω1, ω). A model is of type (α,β) if ...

implies the existence of 0^#.

Statements equivalent to existence

Kunen showed that 0^# exists if and only if there exists a non-trivial elementary embedding for the

''L'' into itself.

Donald A. Martin Donald Anthony Martin (born December 24, 1940), also known as Tony Martin, is an American set theorist and philosopher of mathematics at UCLA, where he is an emeritus professor of mathematics and philosophy. Education and career Martin rece ...

and

Leo Harrington Leo Anthony Harrington (born May 17, 1946) is a professor of mathematics at the University of California, Berkeley who works in recursion theory, model theory, and set theory. Having retired from being a Mathematician, Professor Leo Harrington is ...

have shown that the existence of 0^# is equivalent to the determinacy of lightface analytic games. In fact, the strategy for a universal lightface analytic game has the same

Turing degree In computer science and mathematical logic the Turing degree (named after Alan Turing) or degree of unsolvability of a set of natural numbers measures the level of algorithmic unsolvability of the set. Overview The concept of Turing degree is fund ...

as 0^#. It follows from

Jensen's covering theorem In set theory, Jensen's covering theorem states that if 0# does not exist then every uncountable set of ordinals is contained in a constructible set of the same cardinality. Informally this conclusion says that the constructible universe is clos ...

that the existence of 0^# is equivalent to ω_ω being a

regular cardinal In set theory, a regular cardinal is a cardinal number that is equal to its own cofinality. More explicitly, this means that \kappa is a regular cardinal if and only if every unbounded subset C \subseteq \kappa has cardinality \kappa. Infinite ...

in the constructible universe ''L''. Silver showed that the existence of an uncountable set of indiscernibles in the constructible universe is equivalent to the existence of 0^#.

Consequences of existence and non-existence

Its existence implies that every

uncountable In mathematics, an uncountable set (or uncountably infinite set) is an infinite set that contains too many elements to be countable. The uncountability of a set is closely related to its cardinal number: a set is uncountable if its cardinal numb ...

cardinal Cardinal or The Cardinal may refer to: Animals * Cardinal (bird) or Cardinalidae, a family of North and South American birds **''Cardinalis'', genus of cardinal in the family Cardinalidae **''Cardinalis cardinalis'', or northern cardinal, the ...

in the set-theoretic universe ''V'' is an indiscernible in ''L'' and satisfies all

axioms that are realized in ''L'' (such as being totally ineffable). It follows that the existence of 0^# contradicts the ''

axiom of constructibility The axiom of constructibility is a possible axiom for set theory in mathematics that asserts that every set is constructible universe, constructible. The axiom is usually written as ''V'' = ''L'', where ''V'' and ''L'' denote the von Neumann unive ...

'': ''V'' = ''L''. If 0^# exists, then it is an example of a non-constructible Δ set of integers. This is in some sense the simplest possibility for a non-constructible set, since all Σ and Π sets of integers are constructible. On the other hand, if 0^# does not exist, then the constructible universe ''L'' is the core model—that is, the canonical inner model that approximates the large cardinal structure of the universe considered. In that case,

Jensen's covering lemma In set theory, Jensen's covering theorem states that if 0# does not exist then every uncountable set of ordinals is contained in a constructible set of the same cardinality. Informally this conclusion says that the constructible universe is close ...

holds: :For every uncountable set ''x'' of ordinals there is a constructible ''y'' such that ''x'' ⊂ ''y'' and ''y'' has the same

cardinality In mathematics, the cardinality of a set is a measure of the number of elements of the set. For example, the set A = \ contains 3 elements, and therefore A has a cardinality of 3. Beginning in the late 19th century, this concept was generalized ...

as ''x''. This deep result is due to

Ronald Jensen Ronald Björn Jensen (born April 1, 1936) is an American mathematician who lives in Germany, primarily known for his work in mathematical logic and set theory. Career Jensen completed a BA in economics at American University in 1959, and a Ph.D. ...

. Using forcing it is easy to see that the condition that ''x'' is uncountable cannot be removed. For example, consider

Namba forcing In mathematics, forcing is a method of constructing new models ''M'' 'G''of set theory by adding a generic subset ''G'' of a poset ''P'' to a model ''M''. The poset ''P'' used will determine what statements hold in the new universe (the 'extension' ...

, that preserves

\omega_1

and collapses

\omega_2

to an ordinal of

cofinality In mathematics, especially in order theory, the cofinality cf(''A'') of a partially ordered set ''A'' is the least of the cardinalities of the cofinal subsets of ''A''. This definition of cofinality relies on the axiom of choice, as it uses the ...

\omega

. Let

G

be an

\omega

-sequence cofinal on

\omega_2^L

and

generic Generic or generics may refer to: In business * Generic term, a common name used for a range or class of similar things not protected by trademark * Generic brand, a brand for a product that does not have an associated brand or trademark, other ...

over ''L''. Then no set in ''L'' of ''L''-size smaller than

\omega_2^L

(which is uncountable in ''V'', since

\omega_1

is preserved) can cover

G

, since

\omega_2

is a

Other sharps

If ''x'' is any set, then ''x''^# is defined analogously to 0^# except that one uses L 'x''instead of L. See the section on relative constructibility in

constructible universe In mathematics, in set theory, the constructible universe (or Gödel's constructible universe), denoted by , is a particular class of sets that can be described entirely in terms of simpler sets. is the union of the constructible hierarchy . It w ...

References

* * * * * * *{{Citation , last1=Solovay , first1=Robert M. , title=A nonconstructible Δ{{su, p=1, b=3 set of integers , jstor=1994631 , mr=0211873 , year=1967 , journal=

Transactions of the American Mathematical Society The ''Transactions of the American Mathematical Society'' is a monthly peer-reviewed scientific journal of mathematics published by the American Mathematical Society. It was established in 1900. As a requirement, all articles must be more than 15 p ...