Peano axioms

Addition is a function that maps two natural numbers (two elements of N) to another one. It is defined recursively as:

${\displaystyle {\begin{aligned}a+0&=a,&{\textrm {(1)}}\\a+S(b)&=S(a+b).&{\textrm {(2)}}\end{aligned}}}$

For example:

${\displaystyle {\begin{aligned}a+1&=a+S(0)&{\mbox{by definition}}\\&=S(a+0)&{\mbox{using (2)}}\\&=S(a),&{\mbox{using (1)}}\\\\a+2&=a+S(1)&{\mbox{by definition}}\\&=S(a+1)&{\mbox{using (2)}}\\&=S(S(a))&{\mbox{using }}a+1=S(a)\\\\a+3&=a+S(2)&{\mbox{by definition}}\\&=S(a+2)&{\mbox{using (2)}}\\&=S(S(S(a)))&{\mbox{using }}a+2=S(S(a))\\{\text{etc.}}&\\\end{aligned}}}$

The structure (N, +) is a commutative monoid with identity element 0. (N, +) is also a cancellative magma, and thus embeddable in a group. The smallest group embedding N is the integers.

Similarly, multiplication is a function mapping two natural numbers to another one. Given addition, it is defined recursively as:

${\displaystyle {\begin{aligned}a\cdot 0&=0,\\a\cdot S(b)&=a+(a\cdot b).\end{aligned}}}$

It is easy to see that S(0) (or "1", in the familiar language of decimal representation) is the multiplicative right identity:

a · S(0) = a + (a · 0) = a + 0 = a

To show that S(0) is also the multiplicative left identity requires the induction axiom due to the way multiplication is defined:

• S(0) is the left identity of 0: S(0) · 0 = 0.
• If S(0) is the left identity of a (that is S(0) · a = a), then S(0) is also the left identity of S(a): S(0) · S(a) = S(0) + S(0) · a = S(0) + a = a + S(0) = S(a + 0) = S(a).

Therefore, by the induction axiom S(0) is the multiplicative left identity of all natural numbers. Moreover, it can be shown that multiplication distributes over addition:

a · (b + c) = (a · b) + (a · c).

Thus, (N, +, 0, ·, S(0)) is a commutative semiring.

The usual total order relation ≤ on natural numbers can be defined as follows, assuming 0 is a natural number:

For all a, b ∈ N, a ≤ b if and only if there exists some c ∈ N such that a + c = b.

This relation is stable under addition and multiplication: for ${\displaystyle a,b,c\in \mathbf {N} }$, if a ≤ b, then:

• a + c ≤ b + c, and
• a · c ≤ b · c.

Thus, the structure (N, +, ·, 1, 0, ≤) is an ordered semiring; because there is no natural number between 0 and 1, it is a discrete ordered semiring.

The axiom of induction is sometimes stated in the following form that uses a stronger hypothesis, making use of the order relation "≤":

For any predicate φ, if

• φ(0) is true, and
• for every n, k ∈ N, if k ≤ n implies that φ(k) is true, then φ(S(n)) is true,

then for every n ∈ N, φ(n) is true.

This form of the induction axiom, called strong induction, is a consequence of the standard formulation, but is often better suited for reasoning about the ≤ order. For example, to show that the naturals are well-ordered—every nonempty subset of N has a least element—one can reason as follows. Let a nonempty X ⊆ N be given and assume X has no least element.

• Because 0 is the least element of N, it must be that 0 ∉ X.
• For any n ∈ N, suppose for every k ≤ n, k ∉ X. Then S(n) ∉ X, for otherwise it would be the least element of X.

Thus, by the strong induction principle, for every n ∈ N, n ∉ X. Thus, X ∩ N = ∅, which contradicts X being a nonempty subset of N. Thus X has a least element.

There are many different, but equivalent, axiomatizations of Peano arithmetic. While some axiomatizations, such as the one just described, use a signature that only has symbols for 0 and the successor, addition, and multiplications operations, other axiomatizations use the language of ordered semirings, including an additional order relation symbol. One such axiomatization begins with the following axioms that describe a discrete ordered semiring.[10]

1. ${\displaystyle \forall x,y,z\ ((x+y)+z=x+(y+z))}$, i.e., addition is associative.
2. ${\displaystyle \forall x,y\ (x+y=y+x)}$, i.e., addition is commutative.
3. ${\displaystyle \forall x,y,z\ ((x\cdot y)\cdot z=x\cdot (y\cdot z))}$, i.e., multiplication is associative.
4. ${\displaystyle \forall x,y\ (x\cdot y=y\cdot x)}$, i.e., multiplication is commutative.
5. ${\displaystyle \forall x,y,z\ (x\cdot (y+z)=(x\cdot y)+(x\cdot z))}$, i.e., multiplication distributes over addition.
6. ${\displaystyle \forall x\ (x+0=x\land x\cdot 0=0)}$, i.e., zero is an identity for addition, and an absorbing element for multiplication (actually superfluous[note 1]).
7. ${\displaystyle \forall x\ (x\cdot 1=x)}$, i.e., one is an identity for multiplication.
8. ${\displaystyle \forall x,y,z\ (x<y\land y<z\Rightarrow x<z)}$, i.e., the '<' operator is transitive.
9. ${\displaystyle \forall x\ (\neg (x<x))}$, i.e., the '<' operator is irreflexive.
10. ${\displaystyle \forall x,y\ (x<y\lor x=y\lor y<x)}$, i.e., the ordering satisfies trichotomy.
11. ${\displaystyle \forall x,y,z\ (x<y\Rightarrow x+z<y+z)}$, i.e. the ordering is preserved under addition of the same element.
12. ${\displaystyle \forall x,y,z\ (0<z\land x<y\Rightarrow x\cdot z<y\cdot z)}$, i.e. the ordering is preserved under multiplication by the same positive element.
13. ${\displaystyle \forall x,y\ (x<y\Rightarrow \exists z\ (x+z=y))}$, i.e. given any two distinct elements, the larger is the smaller plus another element.
14. ${\displaystyle 0<1\land \forall x\ (x>0\Rightarrow x\geq 1)}$, i.e. zero and one are distinct and there is no element between them.
15. ${\displaystyle \forall x\ (x\geq 0)}$, i.e. zero is the minimum element.

The theory defined by these axioms is known as PA⁻; the theory PA is obtained by adding the first-order induction schema. An important property of PA⁻ is that any structure ${\displaystyle M}$ satisfying this theory has an initial segment (ordered by ${\displaystyle \leq }$) isomorphic to ${\displaystyle \mathbf {N} }$. Elements in that segment are called standard elements, while other elements are called nonstandard elements.

The Peano axioms can be derived from set theoretic constructions of the natural numbers and axioms of set theory such as ZF.[11] The standard construction of the naturals, due to John von Neumann, starts from a definition of 0 as the empty set, ∅, and an operator s on sets defined as:

${\displaystyle s(a)=a\cup \{a\}}$

The set of natural numbers N is defined as the intersection of all sets closed under s that contain the empty set. Each natural number is equal (as a set) to the set of natural numbers less than it:

${\displaystyle {\begin{aligned}0&=\emptyset \\1&=s(0)=s(\emptyset )=\emptyset \cup \{\emptyset \}=\{\emptyset \}=\{0\}\\2&=s(1)=s(\{0\})=\{0\}\cup \{\{0\}\}=\{0,\{0\}\}=\{0,1\}\\3&=s(2)=s(\{0,1\})=\{0,1\}\cup \{\{0,1\}\}=\{0,1,\{0,1\}\}=\{0,1,2\}\end{aligned}}}$

and so on. The set N together with 0 and the successor function s : N → N satisfies the Peano axioms.

Peano arithmetic is equiconsistent with several weak systems of set theory.[12] One such system is ZFC with the axiom of infinity replaced by its negation. Another such system consists of general set theory (extensionality, existence of the empty set, and the axiom of adjunction), augmented by an axiom schema stating that a property that holds for the empty set and holds of an adjunction whenever it holds of the adjunct must hold for all sets.

The Peano axioms can also be understood using category theory. Let C be a category with terminal object 1_C, and define the category of pointed unary systems, US₁(C) as follows:

• The objects of US₁(C) are triples (X, 0_X, S_X) where X is an object of C, and 0_X : 1_C → X and S_X : X → X are C-morphisms.
• A morphism φ : (X, 0_X, S_X) → (Y, 0_Y, S_Y) is a C-morphism φ : X → Y with φ 0_X = 0_Y and φ S_X = S_Y φ.

Then C is said to satisfy the Dedekind–Peano axioms if US₁(C) has an initial object; this initial object is known as a natural number object in C. If (N, 0, S) is this initial object, and (X, 0_X, S_X) is any other object, then the unique map u : (N, 0, S) → (X, 0_X, S_X) is such that

${\displaystyle {\begin{aligned}u0&=0_{X},\\u(Sx)&=S_{X}(ux).\end{aligned}}}$

This is precisely the recursive definition of 0_X and S_X.

A cut in a nonstandard model M is a nonempty subset C of M so that C is downward closed (x < y and y ∈ C ⇒ x ∈ C) and C is closed under successor. A proper cut is a cut that is a proper subset of M. Each nonstandard model has many proper cuts, including one that corresponds to the standard natural numbers. However, the induction scheme in Peano arithmetic prevents any proper cut from being definable. The overspill lemma, first proved by Abraham Robinson, formalizes this fact.

Overspill Lemma[16] Let M be a nonstandard model of PA and let C be a proper cut of M. Suppose that ${\displaystyle {\bar {a}}}$ is a tuple of elements of M and ${\displaystyle \phi (x,{\bar {a}})}$ is a formula in the language of arithmetic so that

${\displaystyle M\vDash \phi (b,{\bar {a}})}$ for all b ∈ C.

Then there is a c in M that is greater than every element of C such that

${\displaystyle M\vDash \phi (c,{\bar {a}}).}$