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In mathematics, in the subfield of ring theory, a ring R is a polynomial identity ring if there is, for some N > 0, an element P other than 0 of the free algebra, Z<X₁, X₂, ..., X_N>, over the ring of integers in N variables X₁, X₂, ..., X_N such that for all N-tuples r₁, r₂, ..., r_N taken from R it happens that

${\displaystyle P(r_{1},r_{2},\ldots ,r_{N})=0.\ }$

Strictly the X_i here are "non-commuting indeterminates", and so "polynomial identity" is a slight abuse of language, since "polynomial" here stands for what is usually called a "non-commutative polynomial". The abbreviation PI-ring is common. More generally, the free algebra over any ring S may be used, and gives the concept of PI-algebra.

If the degree of the polynomial P is defined in the usual way, the polynomial P is called monic if at least one of its terms of highest degree has coefficient equal to 1.

Every commutative ring is a PI-ring, satisfying the polynomial identity XY - YX = 0. Therefore PI-rings are usually taken as close generalizations of commutative rings. If the ring has characteristic p different from zero then it satisfies the polynomial identity pX = 0. To exclude such examples, sometimes it is defined that PI-rings must satisfy a monic polynomial identity.^[1]

Examples

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

${\displaystyle P(X_{1},X_{2})=X_{1}X_{2}-X_{2}X_{1}=0~}$

• 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

${\displaystyle \det(A)=\sum _{\sigma \in S_{N}}\operatorname {sgn}(\sigma )\prod _{i=1}^{N}a_{i,\sigma (i)}}$

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.

${\displaystyle s_{N}(X_{1},\ldots ,X_{N})=\sum _{\sigma \in S_{N}}\operatorname {sgn}(\sigma )X_{\sigma (1)}\dotsm X_{\sigma (N)}=0~}$

The k×k matrix ring over any commutative ring satisfies a standard identity; the Amitsur–Levitzki theorem states that it satisfies s_2k. The degree of this identity is optimal since the matrix ring can not satisfy any monic polynomial of degree less than 2k.

• 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

e_ie_j = −e_je_i.

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 − xzz − zxy + zyz = 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, ${\displaystyle R\otimes _{\mathbb {Z} }S}$, 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 integal 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 ${\displaystyle p}$ is minimal over ${\displaystyle P\cap K}$) and the incomparability property (If P and Q are prime ideals of R and ${\displaystyle P\subset Q}$ then ${\displaystyle P\cap K\subset Q\cap K}$) 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

${\displaystyle \tau }$:F ${\displaystyle \rightarrow }$ R.

An ideal I of F is called T-ideal if ${\displaystyle f(I)\subset I}$ 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.

References

43 year old Petroleum Engineer Harry from Deep River, usually spends time with hobbies and interests like renting movies, property developers in singapore new condominium and vehicle racing. Constantly enjoys going to destinations like Camino Real de Tierra Adentro.

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• Polynomial identities in ring theory, Louis Halle Rowen, Academic Press, 1980, ISBN 978-0-12-599850-5
• Polynomial identity rings, Vesselin S. Drensky, Edward Formanek, Birkhäuser, 2004, ISBN 978-3-7643-7126-5
• Polynomial identities and asymptotic methods, A. Giambruno, Mikhail Zaicev, AMS Bookstore, 2005, ISBN 978-0-8218-3829-7
• Computational aspects of polynomial identities, Alexei Kanel-Belov, Louis Halle Rowen, A K Peters Ltd., 2005, ISBN 978-1-56881-163-5

External links

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