English

Quasi-immanants

Combinatorics 2025-01-28 v1

Abstract

For an integer partition λ \lambda of nn and an n×nn \times n matrix AA, consider the expansion of the immanant Immλ(A)\text{Imm}^{\lambda}(A) as a sum indexed by permutations σ\sigma of order nn, with coefficients given by the irreducible characters χλ(ctype(σ))\chi^{\lambda}(\text{ctype}(\sigma)) of the symmetric group SnS_{n}, for the cycle type ctype(σ)n\text{ctype}(\sigma) \vdash n of σ\sigma. Skandera et al. have introduced combinatorial interpretations of a generalization of immanants given by replacing the coefficient χλ(ctype(σ))\chi^{\lambda}(\text{ctype}(\sigma)) with preimages with respect to the Frobenius morphism of elements among the distinguished bases of the algebra Sym\textsf{Sym} of symmetric functions. Since Sym \textsf{Sym} is contained in the algebra QSym\textsf{QSym} of quasisymmetric functions, this leads us to further generalize immanants with the use of quasisymmetric functions. Since bases of QSym \textsf{QSym} are indexed by integer compositions, we make use of cycle compositions in place of cycle types to define the family of quasi-immanants introduced in this paper. This is achieved through the use of the quasisymmetric power sum bases due to Ballantine et al., and we prove a combinatorial formula for the coefficients arising in an analogue, given by a special case of quasi-immanants associated with quasisymmetric Schur functions, of second immanants.

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Cite

@article{arxiv.2501.15667,
  title  = {Quasi-immanants},
  author = {John M. Campbell},
  journal= {arXiv preprint arXiv:2501.15667},
  year   = {2025}
}

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R2 v1 2026-06-28T21:18:38.869Z