Hyperelliptic four-manifolds defined by vector-colorings of simple polytopes

Abstract

Toric topology assigns to each simple convex n-polytope P with m facets an n-dimensional real moment angle manifold RZP with a canonical action of Z2m=( Z/2 Z)m. We consider (non-necessarily free) actions of subgroups H⊂ Z2m on RZP. The orbit space N(P,H)= RZP/H has an action of Z2m/H. For general n we introduce the notion of a Hamiltonian C(n,k)-subcomplex in the boundary of an n-polytope P generalizing the notions of a Hamiltonian cycle (k=2), Hamiltonian theta-subgraph (k=3) and Hamiltonian K4-subgraph (k=4) in the 1-skeleton of a 3-polytope. Each C(n,k)-subcomplex C⊂ ∂ P corresponds to a subgroup HC⊂ Z2m such that N(P,HC) Sn. We prove that in dimensions n≤slant 4 this correspondence is a bijection. Any subgroup H⊂ Z2m defines a complex C(P,H)⊂ ∂ P. We prove that each Hamiltonian C(n,k)-subcomplex C⊂ C(P,H) inducing H corresponds to a hyperelliptic involution τC∈ Z2m/H on the manifold N(P,H) (that is, an involution with the orbit space homeomorphic to Sn) and in dimensions n≤slant 4 this correspondence is a bijection. We prove that for the geometries X= S4, S3× R, S2× S2, S2× R2, S2× L2, and L2× L2 there exists a compact right-angled 4-polytope P with a free action of H such that the geometric manifold N(P,H) has a hyperelliptic involution in Z2m/H, and for X= R4, L4, L3× R and L2× R2 there are no such polytopes.

0

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.

Discussion (0)

Sign in to join the discussion.

Loading comments…