Skeleton of isometric Tensor Network States for Abelian String-Net Models
- URL: http://arxiv.org/abs/2511.13821v1
- Date: Mon, 17 Nov 2025 19:00:02 GMT
- Title: Skeleton of isometric Tensor Network States for Abelian String-Net Models
- Authors: Julian Boesl, Yu-Jie Liu, Frank Pollmann, Michael Knap,
- Abstract summary: We construct parametrized isometric tensor network states -- referred to as skeletons -- that allow us to explore phases of abelian topological order.<n>We show that expectation values of generalized Pauli strings of arbitrary weight can be efficiently computed using classical methods.
- Score: 2.7700250131344064
- License: http://arxiv.org/licenses/nonexclusive-distrib/1.0/
- Abstract: We construct parametrized isometric tensor network states -- referred to as skeletons -- that allow us to explore phases of abelian topological order and can be efficiently implemented on quantum processors. We obtain stable finite correlation length deformations of string-net fixed points, which are constructed both by conserving virtual symmetries of the tensor and by imposing local isometry constraints. They connect distinct topological phases via a shared critical point, thereby providing analytically tractable examples of phase transitions beyond anyon condensation. By mapping such classes of 2D tensor networks to 1D stochastic automata with local update rules, we show that expectation values of generalized Pauli strings of arbitrary weight can be efficiently computed using classical methods. Therefore these skeletons not only serve as an organizing principle for abelian topological order but also provide a non-trivial testbed for quantum processors.
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