Pop-Stack Operators for Torsion Classes and Cambrian Lattices
Abstract
The pop-stack operator of a finite lattice L is the map popL L L that sends each element x∈ L to the meet of \x\L(x), where covL(x) is the set of elements covered by x in L. We study several properties of the pop-stack operator of tors, the lattice of torsion classes of a τ-tilting finite algebra over a field K. We describe the pop-stack operator in terms of certain mutations of 2-term simple-minded collections. This allows us to describe preimages of a given torsion class under the pop-stack operator. We then specialize our attention to Cambrian lattices of a finite irreducible Coxeter group W. Using tools from representation theory, we provide simple Coxeter-theoretic and lattice-theoretic descriptions of the image of the pop-stack operator of a Cambrian lattice (which can be stated without representation theory). When specialized to a bipartite Cambrian lattice of type A, this result settles a conjecture of Choi and Sun. We also settle a related enumerative conjecture of Defant and Williams. When L is an arbitrary lattice quotient of the weak order on W, we prove that the maximum size of a forward orbit under the pop-stack operator of L is at most the Coxeter number of W; when L is a Cambrian lattice, we provide an explicit construction to show that this maximum forward orbit size is actually equal to the Coxeter number.
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