Nilpotent

This article is about a type of element in a ring. For the type of group, see Nilpotent group. For the type of ideal, see Nilpotent ideal.

In mathematics, an element, x, of a ring, R, is called nilpotent if there exists some positive integer, n, such that xⁿ = 0.

The term was introduced by Benjamin Peirce in the context of his work on the classification of algebras.^[1]

Examples

This definition can be applied in particular to square matrices. The matrix

A={\begin{pmatrix}0&1&0\\0&0&1\\0&0&0\end{pmatrix}}

is nilpotent because A³ = 0. See nilpotent matrix for more.

In the factor ring Z/9Z, the equivalence class of 3 is nilpotent because 3² is congruent to 0 modulo 9.
Assume that two elements a, b in a (non-commutative) ring R satisfy ab = 0. Then the element c = ba is nilpotent (if non-zero) as c² = (ba)² = b(ab)a = 0. An example with matrices (for a, b):

A={\begin{pmatrix}0&1\\0&1\end{pmatrix}},\;\;B={\begin{pmatrix}0&1\\0&0\end{pmatrix}}.

Here AB = 0, BA = B.

The ring of coquaternions contains a cone of nilpotents.

Properties

No nilpotent element can be a unit (except in the trivial ring {0}, which has only a single element 0 = 1). All non-zero nilpotent elements are zero divisors.

An n-by-n matrix A with entries from a field is nilpotent if and only if its characteristic polynomial is tⁿ.

If x is nilpotent, then 1 − x is a unit, because xⁿ = 0 entails

(1-x)(1+x+x^{2}+\cdots +x^{{n-1}})=1-x^{n}=1.

More generally, the sum of a unit element and a nilpotent element is a unit when they commute.

Commutative rings

The nilpotent elements from a commutative ring $R$ form an ideal ${\mathfrak {N}}$ ; this is a consequence of the binomial theorem. This ideal is the nilradical of the ring. Every nilpotent element $x$ in a commutative ring is contained in every prime ideal ${\mathfrak {p}}$ of that ring, since $x^{n}=0\in {\mathfrak {p}}$ . So ${\mathfrak {N}}$ is contained in the intersection of all prime ideals.

If $x$ is not nilpotent, we are able to localize with respect to the powers of $x$ : $S=\{1,x,x^{2},...\}$ to get a non-zero ring $S^{-1}R$ . The prime ideals of the localized ring correspond exactly to those primes ${\mathfrak {p}}$ with ${\mathfrak {p}}\cap S=\emptyset$ .^[2] As every non-zero commutative ring has a maximal ideal, which is prime, every non-nilpotent $x$ is not contained in some prime ideal. Thus ${\mathfrak {N}}$ is exactly the intersection of all prime ideals.^[3]

A characteristic similar to that of Jacobson radical and annihilation of simple modules is available for nilradical: nilpotent elements of ring R are precisely those that annihilate all integral domains internal to the ring R (that is, of the form R/I for prime ideals I). This follows from the fact that nilradical is the intersection of all prime ideals.

Nilpotent elements in Lie algebra

Let ${\mathfrak {g}}$ be a Lie algebra. Then an element of ${\mathfrak {g}}$ is called nilpotent if it is in $[{\mathfrak {g}},{\mathfrak {g}}]$ and $\operatorname {ad}x$ is a nilpotent transformation. See also: Jordan decomposition in a Lie algebra.

Nilpotency in physics

An operand Q that satisfies Q² = 0 is nilpotent. Grassmann numbers which allow a path integral representation for Fermionic fields are nilpotents since their squares vanish. The BRST charge is an important example in physics.

As linear operators form an associative algebra and thus a ring, this is a special case of the initial definition.^[4]^[5] More generally, in view of the above definitions, an operator Q is nilpotent if there is n∈N such that Qⁿ = 0 (the zero function). Thus, a linear map is nilpotent iff it has a nilpotent matrix in some basis. Another example for this is the exterior derivative (again with n = 2). Both are linked, also through supersymmetry and Morse theory,^[6] as shown by Edward Witten in a celebrated article.^[7]

The electromagnetic field of a plane wave without sources is nilpotent when it is expressed in terms of the algebra of physical space.^[8]

Algebraic nilpotents

The two-dimensional dual numbers contain a nilpotent space. Other algebras and numbers that contain nilpotent spaces include split-quaternions (coquaternions), split-octonions, biquaternions ${\mathbb C}\otimes {\mathbb H}$ , and complex octonions ${\mathbb C}\otimes {\mathbb O}$ .

References

↑ Polcino Milies & Sehgal (2002), An Introduction to Group Rings. p. 127.
↑ Matsumura, Hideyuki (1970). "Chapter 1: Elementary Results". Commutative Algebra. W. A. Benjamin. p. 6. ISBN 978-0-805-37025-6.
↑ Atiyah, M. F.; MacDonald, I. G. (February 21, 1994). "Chapter 1: Rings and Ideals". Introduction to Commutative Algebra. Westview Press. p. 5. ISBN 978-0-201-40751-8.
↑ Peirce, B. Linear Associative Algebra. 1870.
↑ Polcino Milies, César; Sehgal, Sudarshan K. An introduction to group rings. Algebras and applications, Volume 1. Springer, 2002. ISBN 978-1-4020-0238-0
↑ A. Rogers, The topological particle and Morse theory, Class. Quantum Grav. 17:3703–3714,2000 doi:10.1088/0264-9381/17/18/309.
↑ E Witten, Supersymmetry and Morse theory. J.Diff.Geom.17:661–692,1982.
↑ Rowlands, P. Zero to Infinity: The Foundations of Physics, London, World Scientific 2007, ISBN 978-981-270-914-1

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