Polynomial identity ring

Examples

For example, if R is a commutative ring it is a PI-ring: this is true with

The ring of 2 by 2 matrices over a commutative ring satisfies the Hall identity

This identity was used by M. Hall (1943), but was found earlier by Wagner (1937).

A major role is played in the theory by the standard identity s_N, of length N, which generalises the example given for commutative rings (N = 2). It derives from the Leibniz formula for determinants

by replacing each product in the summand by the product of the X_i in the order given by the permutation σ. In other words each of the N! orders is summed, and the coefficient is 1 or −1 according to the signature.The m×m matrix ring over any commutative ring satisfies a standard identity: the Amitsur–Levitzki theorem states that it satisfies s_2m. The degree of this identity is optimal since the matrix ring can not satisfy any monic polynomial of degree less than 2m.

Given a field k of characteristic zero, take R to be the exterior algebra over a countably infinite-dimensional vector space with basis e₁, e₂, e₃, ... Then R is generated by the elements of this basis and

This ring does not satisfy s_N for any N and therefore can not be embedded in any matrix ring. In fact s_N(e₁,e₂,...,e_N) = N!e₁e₂...e_N ≠ 0. On the other hand it is a PI-ring since it satisfies [[x, y], z] := xyz − yxz − zxy + zyx = 0. It is enough to check this for monomials in the e's. Now, a monomial of even degree commutes with every element. Therefore if either x or y is a monomial of even degree [x, y] := xy − yx = 0. If both are of odd degree then [x, y] = xy − yx = 2xy has even degree and therefore commutes with z, i.e. [[x, y], z] = 0.

Properties

Any subring or homomorphic image of a PI-ring is a PI-ring.

A finite direct product of PI-rings is a PI-ring.

A direct product of PI-rings, satisfying the same identity, is a PI-ring.

It can always be assumed that the identity that the PI-ring satisfies is multilinear.

If a ring is finitely generated by n elements as a module over its center then it satisfies every alternating multilinear polynomial of degree larger than n. In particular it satisfies s_N for N > n and therefore it is a PI-ring.

If R and S are PI-rings then their tensor product over the integers, R ⊗ Z S , is also a PI-ring.

If R is a PI-ring, then so is the ring of n×n-matrices with coefficients in R.

PI-rings as generalizations of commutative rings

Among noncommutative rings, PI-rings satisfy the Köthe conjecture. Affine PI-algebras over a field satisfy the Kurosh conjecture, the Nullstellensatz and the catenary property for prime ideals.

If R is a PI-ring and K is a subring of its center such that R is integral over K then the going up and going down properties for prime ideals of R and K are satisfied. Also the lying over property (If p is a prime ideal of K then there is a prime ideal P of R such that p is minimal over P ∩ K ) and the incomparability property (If P and Q are prime ideals of R and P ⊂ Q then P ∩ K ⊂ Q ∩ K ) are satisfied.

The set of identities a PI-ring satisfies

If F := Z<X₁, X₂, ..., X_N> is the free algebra in N variables and R is a PI-ring satisfying the polynomial P in N variables, then P is in the kernel of any homomorphism

τ :F → R.

An ideal I of F is called T-ideal if f ( I ) ⊂ I for every endomorphism f of F.

Given a PI-ring, R, the set of all polynomial identities it satisfies is an ideal but even more it is a T-ideal. Conversely, if I is a T-ideal of F then F/I is a PI-ring satisfying all identities in I. It is assumed that I contains monic polynomials when PI-rings are required to satisfy monic polynomial identities.