Symmetric Functions: Problem Set 1¹

Let λ = (λ₁,λ₂,) be a partition (written as an infinite list, with all but finitely many entries zero). Let m ≥ λ₁,n ≥ λ₁^′. Show that the m + n numbers $λ + n- i(1 ≤ i ≤ n ),n - 1 + j - λ′(1 ≤ j ≤ m ) i j$
are a permutation of {0,1,2,,m + n - 1}.
Let λ,μ be partitions of n such that λ covers μ in the dominance order, i.e., λ > μ and if ν is such that λ ≥ ν ≥ μ, then ν = λ or ν = μ. Show that λ can be obtained by removing one box from the j^th row of μ and moving it to the i^th row, for some i < j.
A matrix of non-negative real numbers is said to be doubly stochastic if its row and column sums are all equal to 1. Let λ,μ be partitions of n. Show that λ dominates μ if and only if there exists a doubly stochastic n×n matrix M such that Mλ = μ (where λ,μ are regarded as column vectors of length n).
Let λ be a partition. The hook-length of λ at x = (i,j) ∈ λ is defined to be $h(x) = (λi - i) + (λ′j - j)+ 1.$
The content of x is defined to be c(x) = j - i. Prove that
$∑ (h (x )2 - c(x)2) = |λ|2. x∈λ$
Show that the set of partitions of n under the dominance order is a lattice. In other words, each pair of partitions of n has a greatest lower bound and a least upper bound.
Let m ≥ 1.
1. Show that the set (m) of strictly decreasing m-tuples of nonnegative integers is in bijection with the set of partitions with at most m parts under the map λλ^† where λ_i^† = λ_i - (m - i) for all i.
2. Let λ ∈(m), 1 ≤ i ≤ m and p ≥ 1. Define u_j = λ_j for j≠i, and u_i = λ_i - p. Assume that the {u_j : 1 ≤ j ≤ m} are all distinct, non-negative integers. Let μ ∈(m) denote the tuple obtained by rearranging the u_j in descending order. Describe the image μ^† of μ under the above bijection.
Let (n) denote the set of partitions of n, and ℕ the set of positive integers. For each r ≥ 1, let

a(r,n) = #{(λ,i) ∈(n) × ℕ : λ_i = r}
b(r,n) = #{(λ,i) ∈(n) × ℕ : m_i(λ) ≥ r}
Show that $a (r,n) = b(r,n) = p(n - r)+ p(n - 2r)+ ...$
where p(m) is the number of partitions of m. Deduce that
$∏ ∏ imi(λ) = ∏ ∏ m (λ )! i≥1 i≥1 i λ∈P(n) λ∈P (n)$
Keep the above notation. Let h(r,n) = #{(λ,x) : λ ∈(n),x ∈ λ and h(x) = r}, where h(x) is the hook-length of λ at x. Show that h(r,n) = ra(r,n).

a(r,n)	= #{(λ,i) ∈(n) × ℕ : λ_i = r}
b(r,n)	= #{(λ,i) ∈(n) × ℕ : m_i(λ) ≥ r}