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Entangled Subspaces through Algebraic Geometry

Quantum Physics 2025-12-19 v2 Mathematical Physics Algebraic Geometry math.MP

Abstract

We propose an algebraic geometry-inspired approach for constructing entangled subspaces within the Hilbert space of a multipartite quantum system. Specifically, our method employs a modified Veronese embedding, restricted to the conic, to define subspaces within the symmetric part of the Hilbert space. By utilizing this technique, we construct the minimal-dimensional, non-orthogonal yet Unextendible Product Basis (nUPB), enabling the decomposition of the multipartite Hilbert space into a two-dimensional subspace, complemented by a Genuinely Entangled Subspace (GES) and a maximal-dimensional Completely Entangled Subspace (CES). In multiqudit systems, we determine the maximum achievable dimension of a symmetric GES and demonstrate its realization through this construction. Furthermore, we systematically investigate the transition from the conventional Veronese embedding to the modified one by imposing various constraints on the affine coordinates, which, in turn, increases the CES dimension while reducing that of the GES.

Keywords

Cite

@article{arxiv.2504.11525,
  title  = {Entangled Subspaces through Algebraic Geometry},
  author = {Masoud Gharahi and Stefano Mancini},
  journal= {arXiv preprint arXiv:2504.11525},
  year   = {2025}
}

Comments

Published version - 25 pages. Your comments are more than welcome

R2 v1 2026-06-28T22:59:38.744Z