{ "id": "1812.00608", "version": "v1", "published": "2018-12-03T08:57:21.000Z", "updated": "2018-12-03T08:57:21.000Z", "title": "Macdonald trees and determinants of representations for finite Coxeter groups", "authors": [ "Arvind Ayyer", "Amritanshu Prasad", "Steven Spallone" ], "comment": "17 pages, 8 figures. This article is a review article; mostly a survey of results in arXiv:1601.01776, arXiv:1604.08837, and arXiv:1710.03039", "categories": [ "math.RT", "math.CO" ], "abstract": "Every irreducible odd dimensional representation of the $n$'th symmetric or hyperoctahedral group, when restricted to the $(n-1)$'th, has a unique irreducible odd-dimensional constituent. Furthermore, the subgraph induced by odd-dimensional representations in the Bratteli diagram of symmetric and hyperoctahedral groups is a binary tree with a simple recursive description. We survey the description of this tree, known as the Macdonald tree, for symmetric groups, from our earlier work. We describe analogous results for hyperoctahedral groups. A partition $\\lambda$ of $n$ is said to be chiral if the corresponding irreducible representation $V_\\lambda$ of $S_n$ has non-trivial determinant. We review our previous results on the structure and enumeration of chiral partitions, and subsequent extension to all Coxeter groups by Ghosh and Spallone. Finally we show that the numbers of odd and chiral partitions track each other closely.", "revisions": [ { "version": "v1", "updated": "2018-12-03T08:57:21.000Z" } ], "analyses": { "subjects": [ "05E10", "20C30", "05A17", "05A15" ], "keywords": [ "finite coxeter groups", "macdonald tree", "hyperoctahedral group", "determinant", "unique irreducible odd-dimensional constituent" ], "tags": [ "review article" ], "note": { "typesetting": "TeX", "pages": 17, "language": "en", "license": "arXiv", "status": "editable" } } }