{"total":12,"items":[{"citing_arxiv_id":"2605.06653","ref_index":46,"ref_count":1,"confidence":0.9,"is_internal_anchor":false,"paper_title":"From Baby Universes to Narain Moduli: Topological Boundary Averaging in SymTFTs","primary_cat":"hep-th","submitted_at":"2026-05-07T17:56:48+00:00","verdict":"UNVERDICTED","verdict_confidence":"LOW","novelty_score":7.0,"formal_verification":"none","one_line_summary":"Ensemble averaging in low-dimensional holography is reinterpreted as averaging over topological boundary conditions in a fixed SymTFT slab, reproducing Poisson moments in the Marolf-Maxfield model and Zamolodchikov measure in the Narain case.","context_count":0,"top_context_role":null,"top_context_polarity":null,"context_text":null},{"citing_arxiv_id":"2604.25821","ref_index":30,"ref_count":1,"confidence":0.9,"is_internal_anchor":false,"paper_title":"Categorical Symmetries via Operator Algebras","primary_cat":"hep-th","submitted_at":"2026-04-28T16:30:42+00:00","verdict":"UNVERDICTED","verdict_confidence":"LOW","novelty_score":6.0,"formal_verification":"none","one_line_summary":"The symmetry category of a 2D QFT with G-symmetry and anomaly k equals the twisted Hilbert space category Hilb^k(G), whose Drinfeld center is the twisted representation category of the conjugation groupoid C*-algebra, enabling braiding computations in the 3D SymTFT.","context_count":1,"top_context_role":"background","top_context_polarity":"background","context_text":"[27] O. Bergman, J.J. Heckman, M. Hübner, D. Migliorati, X. Yu and H.Y. Zhang,On the SymTFTs of Finite Non-Abelian Symmetries,2603.12323. [28] T.D. Brennan and Z. Sun,A SymTFT for continuous symmetries,JHEP12(2024) 100 [2401.06128]. [29] A. Antinucci and F. Benini,Anomalies and gauging of U(1) symmetries,Phys. Rev. B111 (2025) 024110 [2401.10165]. [30] F. Bonetti, M. Del Zotto and R. Minasian,SymTFTs for continuous non-Abelian symmetries,Phys. Lett. B871(2025) 140010 [2402.12347]. [31] F. Apruzzi, F. Bedogna and N. Dondi,SymTh for non-finite symmetries,JHEP04(2026) 153 [2402.14813]. [32] A. Antinucci, F. Benini and G. Rizi,Holographic Duals of Symmetry Broken Phases, Fortsch. Phys.72(2024) 2400172 [2408."},{"citing_arxiv_id":"2604.25820","ref_index":23,"ref_count":1,"confidence":0.9,"is_internal_anchor":false,"paper_title":"Candidate Gaugings of Categorical Continuous Symmetry","primary_cat":"hep-th","submitted_at":"2026-04-28T16:28:19+00:00","verdict":"UNVERDICTED","verdict_confidence":"LOW","novelty_score":6.0,"formal_verification":"none","one_line_summary":"Candidate modular invariants and gaugings for continuous G-symmetries with anomaly k are obtained from +1 eigenspaces of semiclassical modular kernels in a BF+kCS SymTFT model.","context_count":1,"top_context_role":"background","top_context_polarity":"background","context_text":"gaugings - hence equivalently candidate Lagrangian algebra data - ofZ(C k(G)) are ex- pected to be encoded in its algebraic data. Since a SymTFT is, after all, a TQFT, the problem then becomes one of identifying a suitable working TQFT model and extracting from it the physical data that should correspond to algebraic data in the would-be center. It has been proposed in [23, 24] that the 3d TQFT associated to a 2d QFTTwith anomaly-free globalG-symmetry for simple and simply-connected compact Lie groupGis theBFtheory with gauge groupG 1. Moreover, when there exists a 't Hooft anomaly labeled by an integerk∈H 4(BG,Z), the TQFT becomes the combination of theBF theory and the level-kChern-Simons theory [25]. In this paper, we use this TQFT as"},{"citing_arxiv_id":"2604.15424","ref_index":25,"ref_count":1,"confidence":0.9,"is_internal_anchor":false,"paper_title":"SymTFT in Superspace","primary_cat":"hep-th","submitted_at":"2026-04-16T18:00:01+00:00","verdict":"UNVERDICTED","verdict_confidence":"LOW","novelty_score":7.0,"formal_verification":"none","one_line_summary":"A supersymmetric SymTFT (SuSymTFT) is constructed as a super-BF theory on (n|m)-dimensional supermanifolds and verified for compact and chiral super-bosons in two dimensions.","context_count":1,"top_context_role":"background","top_context_polarity":"background","context_text":"Zheng,Symmetry TFTs and anomalies of non-invertible symmetries,J. High Energy Phys.10(2023) 053, [arXiv:2301.07112]. [23] T. D. Brennan and Z. Sun,A SymTFT for continuous symmetries,J. High Energy Phys.12(2024) 100, [arXiv:2401.06128]. [24] A. Antinucci and F. Benini,Anomalies and gauging of U(1) symmetries,Phys. Rev. B111(2025), no. 2 024110, [arXiv:2401.10165]. [25] F. Bonetti, M. Del Zotto, and R. Minasian,SymTFTs for continuous non-Abelian symmetries,Phys. Lett. B871(2025) 140010, [arXiv:2402.12347]. [26] F. Apruzzi, N. Dondi, I. García Etxebarria, H. T. Lam, and S. Schäfer-Nameki, Symmetry TFTs for continuous spacetime symmetries, 2025. [27] Q. Jia, R. Luo, J. Tian, Y.-N. Wang, and Y. Zhang,Symmetry Topological Field"},{"citing_arxiv_id":"2604.14275","ref_index":61,"ref_count":1,"confidence":0.9,"is_internal_anchor":false,"paper_title":"Generalized Complexity Distances and Non-Invertible Symmetries","primary_cat":"hep-th","submitted_at":"2026-04-15T18:00:00+00:00","verdict":"UNVERDICTED","verdict_confidence":"LOW","novelty_score":7.0,"formal_verification":"none","one_line_summary":"Non-invertible symmetries define quantum gates with generalized complexity distances, and simple objects in symmetry categories turn out to be computationally complex in concrete 4D and 2D QFT examples.","context_count":1,"top_context_role":"background","top_context_polarity":"background","context_text":"Garc' ıa Etxebarria, \"SymTFTs forU(1) symmetries from descent,\" arXiv:2411.15126 [hep-th]. [59] M. Cvetiˇ c, R. Donagi, J. J. Heckman, M. H¨ ubner, and E. Torres, \"Cornering relative symmetry theories,\"Phys. Rev. D111no. 8, (2025) 085026,arXiv:2408.12600 [hep-th]. [60] L. Bhardwaj, C. Copetti, D. Pajer, and S. Schafer-Nameki, \"Boundary SymTFT,\" SciPost Phys.19no. 2, (2025) 061,arXiv:2409.02166 [hep-th]. [61] F. Bonetti, M. Del Zotto, and R. Minasian, \"SymTFTs for Continuous non-Abelian Symmetries,\"arXiv:2402.12347 [hep-th]. [62] F. Apruzzi, F. Bedogna, and N. Dondi, \"SymTh for non-finite symmetries,\" arXiv:2402.14813 [hep-th]. [63] X. Yu, \"Gauging in parameter space: A top-down perspective,\"Phys. Rev. D112 no. 2, (2025) 025020,arXiv:2411.14997 [hep-th]."},{"citing_arxiv_id":"2604.09126","ref_index":8,"ref_count":1,"confidence":0.9,"is_internal_anchor":false,"paper_title":"Lattice Realizations of Flat Gauging and T-duality Defects at Any Radius","primary_cat":"hep-th","submitted_at":"2026-04-10T09:09:23+00:00","verdict":"UNVERDICTED","verdict_confidence":"LOW","novelty_score":8.0,"formal_verification":"none","one_line_summary":"Modified Villain lattice realizations of flat-gauged interfaces and T-duality defects in the 2D compact boson are constructed at arbitrary radii, yielding non-compact edge modes with continuous spectrum and infinite quantum dimension.","context_count":1,"top_context_role":"background","top_context_polarity":"background","context_text":"Schafer-Nameki,ICTP lectures on (non-)invertible generalized symmetries,Phys. Rept. 1063(2024) 1-55, arXiv:2305.18296 [hep-th]. [6] T. D. Brennan and Z. Sun,A SymTFT for continuous symmetries,JHEP12(2024) 100, arXiv:2401.06128 [hep-th]. [7] A. Antinucci and F. Benini,Anomalies and gauging of U(1) symmetries,Phys. Rev. B111 (2025) 024110, arXiv:2401.10165 [hep-th]. [8] F. Bonetti, M. Del Zotto, and R. Minasian,SymTFTs for continuous non-Abelian symmetries,Phys. Lett. B871(2025) 140010, arXiv:2402.12347 [hep-th]. [9] A. Arbalestrier, R. Argurio, and L. Tizzano,Noninvertible axial symmetry in QED comes full circle,Phys. Rev. D110(2024) 105012, arXiv:2405.06596 [hep-th]. [10] R. Argurio, A. Collinucci, G. Galati, O."},{"citing_arxiv_id":"2603.12323","ref_index":35,"ref_count":1,"confidence":0.9,"is_internal_anchor":false,"paper_title":"On the SymTFTs of Finite Non-Abelian Symmetries","primary_cat":"hep-th","submitted_at":"2026-03-12T18:00:02+00:00","verdict":"UNVERDICTED","verdict_confidence":"LOW","novelty_score":7.0,"formal_verification":"none","one_line_summary":"Constructs BF-like 3D SymTFT Lagrangians for finite non-Abelian groups presented as extensions, yielding surface-attaching non-genuine line operators and Drinfeld-center fusion rules.","context_count":0,"top_context_role":null,"top_context_polarity":null,"context_text":null},{"citing_arxiv_id":"2602.11696","ref_index":77,"ref_count":1,"confidence":0.9,"is_internal_anchor":false,"paper_title":"Symmetry Spans and Enforced Gaplessness","primary_cat":"cond-mat.str-el","submitted_at":"2026-02-12T08:22:02+00:00","verdict":"UNVERDICTED","verdict_confidence":"LOW","novelty_score":8.0,"formal_verification":"none","one_line_summary":"Symmetry spans enforce gaplessness when a symmetry E embedded into two larger symmetries C and D has no compatible gapped phase that restricts from both.","context_count":1,"top_context_role":"background","top_context_polarity":"background","context_text":"[75] Federico Bonetti, Michele Del Zotto, and Ruben Minasian, \"SymTFTs for continuous non-Abelian symmetries,\" Phys. Lett. B871, 140010 (2025), arXiv:2402.12347 [hep-th]. [76] Riccardo Argurio, Francesco Benini, Matteo Bertolini, Giovanni Galati, and Pierluigi Niro, \"On the symmetry TFT of Yang-Mills-Chern-Simons theory,\" JHEP07, 130 (2024), arXiv:2404.06601 [hep-th]. [77] Finn Gagliano and I˜ naki Garc' ıa Etxebarria, \"SymTFTs forU(1) symmetries from descent,\" (2024), arXiv:2411.15126 [hep-th]. [78] Mirjam Cvetiˇ c, Jonathan J. Heckman, Max H¨ ubner, and Chitraang Murdia, \"Metric isometries, holography, and continuous symmetry operators,\" Phys. Rev. D 112, 106020 (2025), arXiv:2501.17911 [hep-th]. [79] Federico Bonetti, Michele Del Zotto, and Ruben Mi-"},{"citing_arxiv_id":"2602.09105","ref_index":64,"ref_count":1,"confidence":0.9,"is_internal_anchor":false,"paper_title":"Generalized Families of QFTs","primary_cat":"hep-th","submitted_at":"2026-02-09T19:00:17+00:00","verdict":null,"verdict_confidence":null,"novelty_score":null,"formal_verification":null,"one_line_summary":null,"context_count":1,"top_context_role":"background","top_context_polarity":"background","context_text":"Sun, \"A SymTFT for continuous symmetries,\"JHEP12(2024) 100, arXiv:2401.06128 [hep-th]. [62] A. Antinucci, C. Copetti, and S. Schafer-Nameki, \"SymTFT for (3+1)d Gapless SPTs and Obstructions to Confinement,\"SciPost Phys.18(2025) 114,arXiv:2408.05585 [hep-th]. [63] A. Antinucci and F. Benini, \"Anomalies and gauging of U(1) symmetries,\"Phys. Rev. B111 no. 2, (2025) 024110,arXiv:2401.10165 [hep-th]. [64] F. Bonetti, M. Del Zotto, and R. Minasian, \"SymTFTs for Continuous non-Abelian Symmetries,\"arXiv:2402.12347 [hep-th]. [65] M. Del Zotto, S. N. Meynet, and R. Moscrop, \"Remarks on geometric engineering, symmetry TFTs and anomalies,\"JHEP07(2024) 220,arXiv:2402.18646 [hep-th]. [66] F. Apruzzi, F. Bedogna, and N. Dondi, \"SymTh for non-finite symmetries,\""},{"citing_arxiv_id":"2602.03926","ref_index":29,"ref_count":1,"confidence":0.9,"is_internal_anchor":false,"paper_title":"The Line, the Strip and the Duality Defect","primary_cat":"hep-th","submitted_at":"2026-02-03T19:00:00+00:00","verdict":"UNVERDICTED","verdict_confidence":"LOW","novelty_score":7.0,"formal_verification":"none","one_line_summary":"Condensation defects in SymTFT descriptions of XY-plaquette and XYZ-cube models realize non-invertible self-duality symmetries at any coupling, with a continuous SO(2) version in the XY-plaquette.","context_count":0,"top_context_role":null,"top_context_polarity":null,"context_text":null},{"citing_arxiv_id":"2601.18892","ref_index":41,"ref_count":1,"confidence":0.9,"is_internal_anchor":false,"paper_title":"Non-Abelian and Type-A Conformal Anomalies from Euler Descent","primary_cat":"hep-th","submitted_at":"2026-01-26T19:02:22+00:00","verdict":"CONDITIONAL","verdict_confidence":"LOW","novelty_score":7.0,"formal_verification":"none","one_line_summary":"Non-Abelian conformal anomalies are classified via Stora-Zumino descent from the Euler class, placing them on equal footing with perturbative anomalies and enabling WZW terms for anomaly matching.","context_count":0,"top_context_role":null,"top_context_polarity":null,"context_text":null},{"citing_arxiv_id":"2504.11449","ref_index":29,"ref_count":1,"confidence":0.9,"is_internal_anchor":false,"paper_title":"SymTFT construction of gapless exotic-foliated dual models","primary_cat":"cond-mat.str-el","submitted_at":"2025-04-15T17:57:58+00:00","verdict":"UNVERDICTED","verdict_confidence":"LOW","novelty_score":7.0,"formal_verification":"none","one_line_summary":"Develops a Mille-feuille SymTFT construction that generates foliated and exotic dual bulk theories realizing gapless boundary models with spontaneous continuous subsystem symmetry breaking, including duals of the XY plaquette and XYZ cube models.","context_count":0,"top_context_role":null,"top_context_polarity":null,"context_text":null}],"limit":50,"offset":0}