2019
DOI: 10.1007/jhep10(2019)010
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3d modularity

Abstract: We find and propose an explanation for a large variety of modularity-related symmetries in problems of 3-manifold topology and physics of 3d N = 2 theories where such structures a priori are not manifest. These modular structures include: mock modular forms, SL(2, Z) Weil representations, quantum modular forms, non-semisimple modular tensor categories, and chiral algebras of logarithmic CFTs.

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Cited by 86 publications
(166 citation statements)
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References 129 publications
(291 reference statements)
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“…Also the relation between 3d supersymmetric field theories and VOAs has been recently explored in the context of 3d Modulatiry [40] and study of 4-manifolds [41]. It would be also interesting to study these issues related to N = (0, 4) boundary conditions.…”
Section: Future Workmentioning
confidence: 99%
“…Also the relation between 3d supersymmetric field theories and VOAs has been recently explored in the context of 3d Modulatiry [40] and study of 4-manifolds [41]. It would be also interesting to study these issues related to N = (0, 4) boundary conditions.…”
Section: Future Workmentioning
confidence: 99%
“…These manifolds, which also occur as the boundary of plumbed four-manifolds, are sometimes called plumbed three-manifolds, a special case of which are Seifert manifolds. Similar Lagrangians for the 3d theories associated to these manifolds were studied in [6,[18][19][20][21][22][23].In the following we point out new features related to the global structure of the gauge groups and higher-form symmetries of these theories, as well as the explicit computation of the Witten index and related observables. The approach we take is as follows: 1.…”
mentioning
confidence: 77%
“…The vanishing of the degree can always be assumed using (2.11) and (2.12). Then, the graph Ω (k i ) 23 for the Seifert manifolds that we are interested in is given by figure 10. In order to guarantee that this corresponds to a Seifert manifold we have to impose k 5 = 1. and q > 0 for simplicity.…”
Section: Seifert Quiversmentioning
confidence: 99%
“…Apart from its intrinsic importance in differential topology, the η-invariant has a number of interesting physics applications, for example, in the analysis of global gravitational anomalies [16], in fermion fractionization [17,18] , in relation to spectral flow in quantum chromodynamics [19,20], and more recently in the description of symmetry-protected phases of topological insulators (see [21] for a recent review). Similarly, apart from their intrinsic interest in number theory [22,23], mock modular forms and their cousins have come to play an important role in the physics of quantum black holes and quantum holography [2], in umbral moonshine [24,25], in the context of WRT invariants [26][27][28][29] , and more generally in the context of elliptic genera of noncompact SCFTs [30][31][32][33][34][35]. We expect our results will have useful implications in these diverse contexts.…”
Section: Introductionmentioning
confidence: 82%
“…which can be viewed as a τ 2 → 0 − limit of the false theta function for a = k and b = l using the fact that sgn ( + 2kn) = sgn(n) for positive k and 0 ≤ l < 2k. In this limit, the functions f (τ 1 ) have appeared in the computation of topological invariants of Seifert manifolds with three singular fibers [29]. See [29] for a discussion of quantum modular forms and the relation to mock and false theta functions in the context of Chern-Simons theory and WRT invariants [26-28, 60, 61].…”
Section: The η-Invariant and Quantum Modular Formsmentioning
confidence: 99%