English

Complete Homogeneous Varieties via Representation Theory

Algebraic Geometry 2016-04-01 v1 Combinatorics Representation Theory

Abstract

Given an algebraic variety XPNX\subset\mathbb{P}^N with stabilizer HH, the quotient PGLN+1/HPGL_{N+1}/H can be interpreted a parameter space for all PGLN+1PGL_{N+1}-translates of XX. We define XX to be a homogeneous variety\textit{homogeneous variety} if HH acts on it transitively, and satisfies a few other properties, such as HH being semisimple. Some examples of homogeneous varieties are quadric hypersurfaces, rational normal curves, and Veronese and Segre embeddings. In this case, we construct new compactifications of the parameter spaces PGLN+1/HPGL_{N+1}/H, obtained compactifying PGLN+1PGL_{N+1} to the classically known space of \textit{complete collineations}, and taking the G.I.T. quotient by HH, and we will call the result space of \textit{complete homogeneous varieties}; this extends the same construction for quadric hypersurfaces in [36]. We establish a few properties of these spaces: in particular, we find a formula for the volume of divisors that depends only on the dimension of HH-invariants in irreducible representations of SLN+1SL_{N+1}. We then develop some tools in invariant theory, combinatorics and spline approximation to calculate such invariants, and carry out the entire calculations for the case of SL2SL_2-invariants in irreducible representations of SL4SL_4, that gives us explicit values for the volume function in the case of XX being a twisted cubic. Afterwards, we focus our attention on the case of twisted cubics, giving a more explicit description of these compactifications, including the relation with the previously known moduli spaces. In the end, we make some conjectures about how the volume function might be used in solving some enumerative problems.

Keywords

Cite

@article{arxiv.1603.09705,
  title  = {Complete Homogeneous Varieties via Representation Theory},
  author = {Francesco Cavazzani},
  journal= {arXiv preprint arXiv:1603.09705},
  year   = {2016}
}

Comments

Ph. D. Thesis, vii+90 pages

R2 v1 2026-06-22T13:22:36.635Z