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plethysm

In algebra, plethysm is an operation on symmetric functions introduced by Dudley E. Littlewood,{{harvs|txt|last=Littlewood|year1=1936|loc1=p. 52|year2=1944|loc2=p. 329|author-link=Dudley Ernest Littlewood}} who denoted it by {λ} ⊗ {μ}. The word "plethysm" for this operation (after the Greek word πληθυσμός meaning "multiplication") was introduced later by {{harvs|txt|last=Littlewood|year1=1950|loc1=p. 289|year2=1950b|loc2=p.274}}, who said that the name was suggested by M. L. Clark.

If symmetric functions are identified with operations in lambda rings, then plethysm corresponds to composition of operations.

In representation theory

Let V be a vector space over the complex numbers, considered as a representation of the general linear group GL(V). Each Young diagram λ corresponds to a Schur functor Lλ(-) on the category of GL(V)-representations. Given two Young diagrams λ and μ, consider the decomposition of Lλ(Lμ(V)) into a direct sum of irreducible representations of the group. By the representation theory of the general linear group we know that each summand is isomorphic to L_\nu(V) for a Young diagram \nu. So for some nonnegative multiplicities a_{\lambda,\mu,\nu} there is an isomorphism

:L_\lambda(L_\mu(V)) = \bigoplus_{\nu} L_\nu(V)^{\oplus a_{\lambda, \mu, \nu}}.

The problem of (outer) plethysm is to find an expression for the multiplicities a_{\lambda, \mu, \nu}.{{cite book| first=Jerzy | last=Weyman | title = Cohomology of Vector Bundles and Syzygies | year = 2003 | publisher = Cambridge University Press | isbn = 9780511546556 | doi = 10.1017/CBO9780511546556}}

This formulation is closely related to the classical question. The character of the GL(V)-representation Lλ(V) is a symmetric function in dim(V) variables, known as the Schur polynomial sλ corresponding to the Young diagram λ. Schur polynomials form a basis in the space of symmetric functions. Hence to understand the plethysm of two symmetric functions it would be enough to know their expressions in that basis and an expression for a plethysm of two arbitrary Schur polynomials {sλ}⊗{sμ} . The second piece of data is precisely the character of Lλ(Lμ(V)).

References

{{reflist}}

  • {{citation|zbl=0013.14602

|last=Littlewood|first= D. E.

|title=Polynomial concomitants and invariant matrices

|journal= J. London Math. Soc. |volume=11|issue=1|pages= 49–55 |year=1936

|doi=10.1112/jlms/s1-11.1.49}}

  • {{citation|mr=0010594

|last=Littlewood|first= D. E.

|title=Invariant theory, tensors and group characters

|journal=Philosophical Transactions of the Royal Society A |volume= 239|year=1944|issue=807 |pages= 305–365

|jstor=91389|doi=10.1098/rsta.1944.0001|doi-access=free}}

  • {{Citation | last1=Littlewood | first1=Dudley E. | title=The theory of group characters and matrix representations of groups | url=https://www.ams.org/bookstore?fn=20&arg1=alggeom&item=CHEL-357-H | publisher=AMS Chelsea Publishing, Providence, RI | isbn=978-0-8218-4067-2 | mr=0002127 | year=1950}}
  • {{citation|mr=0045079

|last=Littlewood|first= D. E.

|title=A University Algebra|publisher= William Heinemann, Ltd.|place= Melbourne, London, Toronto|year= 1950b|url=https://books.google.com/books?id=pu3uAAAAMAAJ&q=Clark}}

Category:Symmetric functions