English

Quiver combinatorics for higher-dimensional triangulations

Combinatorics 2021-12-23 v1 Representation Theory

Abstract

We investigate the combinatorics of quivers that arise from triangulations of even-dimensional cyclic polytopes. Work of Oppermann and Thomas pinpoints such quivers as the prototypes for higher-dimensional cluster theory. We first show that a 2d2d-dimensional triangulation has no interior (d+1)(d + 1)-simplices if and only if its quiver is a cut quiver of type AA, in the sense of Iyama and Oppermann. This is a higher-dimensional generalisation of the fact that triangulations of polygons with no interior triangles correspond to orientations of an AnA_{n} Dynkin diagram. An application of this first result is that the set of triangulations of a 2d2d-dimensional cyclic polytope with no interior (d+1)(d + 1)-simplices is connected via bistellar flips -- the higher-dimensional analogue of flipping a diagonal inside a quadrilateral. In dimensions higher than 2, bistellar flips cannot be performed at all locations in a triangulation. Our second result gives a quiver-theoretic criterion for performing bistellar flips on a triangulation of a 2d2d-dimensional cyclic polytope. This provides a visual tool for studying mutability of higher-dimensional triangulations and points towards what a theory of higher-dimensional quiver mutation could look like. Indeed, we apply this result to give a rule for mutating cut quivers at vertices which are not necessarily sinks or sources.

Keywords

Cite

@article{arxiv.2112.09189,
  title  = {Quiver combinatorics for higher-dimensional triangulations},
  author = {Nicholas J. Williams},
  journal= {arXiv preprint arXiv:2112.09189},
  year   = {2021}
}

Comments

26 pages, 9 figures

R2 v1 2026-06-24T08:21:08.521Z