English

Homogeneous C21 Models

Complex Variables 2021-04-21 v1 Differential Geometry

Abstract

Fels-Kaup (Acta Mathematica 2008) classified homogeneous C2,1\mathfrak{C}_{2,1} hypersurfaces M5C3M^5 \subset \mathbb{C}^3 and discovered that they are all biholomorphic to tubes S2×iR3S^2 \times i \mathbb{R}^3 over some affinely homogeneous surface S2R3S^2 \subset \mathbb{R}^3. The second and third authors in 2003.08166, by performing highly non-straightforward calculations, conducted the Cartan method of equivalence to classify homogeneous models of PDE systems related to such C2,1\mathfrak{C}^{2,1} hypersurfaces M5C3M^5 \subset \mathbb{C}^3. Kolar-Kossovskiy 1905.05629 and the authors 2003.01952 constructed a formal and a convergent Poincar\'e-Moser normal form for C2,1\mathfrak{C}_{2,1} hypersurfaces M5C3M^5 \subset \mathbb{C}^3. But this was only a first, preliminary step. Indeed, the invariant branching tree underlying Fels-Kaup's classification was still missing in the literature, due to computational obstacles. The present work applies the power series method of equivalence, confirms Fels-Kaup 2008, and finds a differential-invariant tree. To terminate the middle (thickest) branch, it is necessary to compute up to order 1010 with 55 variables. Again, calculations, done by hand, are non-straightforward.

Keywords

Cite

@article{arxiv.2104.09608,
  title  = {Homogeneous C21 Models},
  author = {Wei-Guo Foo and Joel Merker and Pawel Nurowski and The-Anh Ta},
  journal= {arXiv preprint arXiv:2104.09608},
  year   = {2021}
}
R2 v1 2026-06-24T01:20:55.792Z