In mathematics, specifically in ring theory, a nilpotent algebra over a commutative ring is an algebra over a commutative ring, in which for some positive integer n every product containing at least n elements of the algebra is zero. The concept of a nilpotent Lie algebra has a different definition, which depends upon the Lie bracket. (There is no Lie bracket for many algebras over commutative rings; a Lie algebra involves its Lie bracket, whereas, there is no Lie bracket defined in the general case of an algebra over a commutative ring.) Another possible source of confusion in terminology is the quantum nilpotent algebra,[1] a concept related to quantum groups and Hopf algebras.
Formal definition
editAn associative algebra over a commutative ring is defined to be a nilpotent algebra if and only if there exists some positive integer such that for all in the algebra . The smallest such is called the index of the algebra .[2] In the case of a non-associative algebra, the definition is that every different multiplicative association of the elements is zero.
Nil algebra
editA power associative algebra in which every element of the algebra is nilpotent is called a nil algebra.[3]
Nilpotent algebras are trivially nil, whereas nil algebras may not be nilpotent, as each element being nilpotent does not force products of distinct elements to vanish.
See also
edit- Algebraic structure (a much more general term)
- nil-Coxeter algebra
- Lie algebra
- Example of a non-associative algebra
References
edit- ^ Goodearl, K. R.; Yakimov, M. T. (1 Nov 2013). "Unipotent and Nakayama automorphisms of quantum nilpotent algebras". arXiv:1311.0278 [math.QA].
- ^ Albert, A. Adrian (2003) [1939]. "Chapt. 2: Ideals and Nilpotent Algebras". Structure of Algebras. Colloquium Publications, Col. 24. Amer. Math. Soc. p. 22. ISBN 0-8218-1024-3. ISSN 0065-9258; reprint with corrections of revised 1961 edition
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: CS1 maint: postscript (link) - ^ Nil algebra – Encyclopedia of Mathematics
- Lang, Serge (2002), Algebra, Graduate Texts in Mathematics, vol. 211 (Revised third ed.), New York: Springer-Verlag, ISBN 978-0-387-95385-4, MR 1878556