Generalized Symmetry as a Diagnostic Lens: How Non-Invertible Symmetries, Condensable Algebras, and Order-Parameter Structure Reorganize the Classification of Gapped Phases and Phase Transitions

A candidate reading of seven recent preprints from cond-mat.str-el and physics.atom-ph suggests that the classical toolkit for classifying gapped phases and their transitions—built on Landau symmetry breaking, local order parameters, and invertible group symmetries—requires systematic extension at the level of microscopic algebraic structure, not merely at the phenomenological level. The emerging picture, drawn from the corpus, is that *generalized symmetries* (non-invertible, categorical, and higher-form) impose precise algebraic constraints on what constitutes a valid order parameter, what boundary conditions are permissible, and which phase transitions can occur without any form of spontaneous symmetry breaking, even after arbitrary gauging. Concretely: (i) condensable algebras in 2+1d topological orders classify gapped boundaries, and twin algebras sharing identical anyon content but inequivalent algebra structure describe physically distinct phases with isomorphic ground-state degeneracy but inequivalent order parameters [corpus:arxiv:2605.31602]; (ii) these twin phases can undergo direct transitions that are provably beyond-Landau even after partial gauging [corpus:arxiv:2605.31601]; (iii) string order parameters in 1d systems organize into Lagrangian algebras in the Drinfel'd center of the symmetry category, making the fusion rule of the symmetry category—not just its representation theory—the operative diagnostic [corpus:arxiv:2605.27193]; (iv) non-invertible symmetry-breaking transitions can be mapped via generalized gauging to deconfined quantum critical points, and vice versa, establishing a precise duality [corpus:arxiv:2605.27672]; and (v) non-invertible symmetry enriched topological orders (NI-SETOs) can be constructed from string-net models, extending symmetry enrichment beyond the group-theoretic setting [corpus:arxiv:2605.28794]. Two additional corpus entries—a Rydberg spin-chain study [corpus:arxiv:2605.27166] and a topological lattice gauge theory paper [corpus:arxiv:2605.28688]—provide microscopic anchoring and structural context, respectively. The central falsification path is explicit: if a twin-phase transition can be shown to spontaneously break some hidden symmetry after arbitrary gauging, the framework collapses. Concrete tensor-network (DMRG/MPS) constructions of twin-phase order parameters in 1+1d would constitute a direct test. ---

Authorship: Saluca Agentic AI Research Team (Saluca LLC). AI-drafted from arXiv preprint corpus on the date in the filename.

Cited arXiv preprints: 2605.27166, 2605.27193, 2605.27672, 2605.28688, 2605.28794, 2605.29745, 2605.29875, 2605.30421, 2605.31185, 2605.31540, 2605.31601, 2605.31602