English

Noncommutative symmetric functions

High Energy Physics - Theory 2008-02-03 v1 Quantum Algebra

Abstract

This paper presents a noncommutative theory of symmetric functions, based on the notion of quasi-determinant. We begin with a formal theory, corresponding to the case of symmetric functions in an infinite number of independent variables. This allows us to endow the resulting algebra with a Hopf structure, which leads to a new method for computing in descent algebras. It also gives unified reinterpretation of a number of classical constructions. Next, we study the noncommutative analogs of symmetric polynomials. One arrives at different constructions, according to the particular kind of application under consideration. For example, when a polynomial with noncommutative coefficients in one central variable is decomposed as a product of linear factors, the roots of these factors differ from those of the expanded polynomial. Thus, according to whether one is interested in the construction of a polynomial with given roots or in the expansion of a product of linear factors, one has to consider two distinct specializations of the formal symmetric functions. A third type appears when one looks for a noncommutative generalization of applications related to the notion of characteristic polynomial of a matrix. This construction can be applied, for instance, to the noncommutative matrices formed by the generators of the universal enveloping algebra U(gln)U(gl_n) or of

Keywords

Cite

@article{arxiv.hep-th/9407124,
  title  = {Noncommutative symmetric functions},
  author = {Israel Gelfand and D. Krob and Alain Lascoux and B. Leclerc and V. S. Retakh and J. -Y. Thibon},
  journal= {arXiv preprint arXiv:hep-th/9407124},
  year   = {2008}
}

Comments

111 pages