Counting Fq-points of orbital varieties in ad-nilpotent ideals of type An
Abstract
Let bn( Fq) denote the Lie algebra of upper triangular n× n matrices over the finite field Fq, and let un( Fq) be the nilradical of bn. For every bn( Fq)-stable ideal a of un( Fq), and every partition μ of n, we prove two formulas for the number of elements of a of Jordan type μ: the first one is the Hall scalar product of a modified Hall-Littlewood function indexed by μ and a chromatic quasisymmetric function associated to a, and the second one is in terms of an explicit collection of standard tableaux. In the special case that a is the nilradical u( Fq) of the parabolic subalgebra associated to a composition of n, our first formula reduces to a result of Karp and Thomas: up to an explicit polynomial factor in q, the number of elements in u( Fq) of Jordan type μ is equal to the coefficient of the monomial x in the specialization of the dual Macdonald symmetric function Qμ'( x;q-1,t) at t=0. We give three applications: (1) a formula for the number of points of a nilpotent Hessenberg variety, (2) a formula for the number of X∈ u( Fq) that satisfy X2=0, which in the special case =(1n) is different from the Kirillov-Melnikov-Ekhad-Zeilberger formula, and (3) a formula for the number of double cosets U1n( Fq)/ U2 where U1 and U2 are unipotent subgroups corresponding to two bn( Fq)-stable ideals.
Turn this paper into a full lesson
ArcXiv compiles a staged curriculum from this paper: 8-12 lessons across beginner → advanced, synthesised section guides, visuals, flashcards, a quiz, exercises, and on-demand deep dives per section. Grounded in the abstract, never invented.