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Bi-gravity with a single graviton
Auteur(s): Alexandrov S., Speziale Simone
(Article) Publié:
Journal Of High Energy Physics, vol. p.070 (2019)
Texte intégral en Openaccess :
Ref HAL: hal-02114493_v1
Ref Arxiv: 1904.11906
DOI: 10.1007/JHEP08(2019)070
WoS: WOS:000483191300001
Ref. & Cit.: NASA ADS
Exporter : BibTex | endNote
1 Citation
Résumé: We analyze a bi-gravity model based on the first order formalism, having as fundamental variables two tetrads but only one Lorentz connection. We show that on a large class of backgrounds its linearization agrees with general relativity. At the non-linear level, additional degrees of freedom appear, and we reveal the mechanism hiding them around the special backgrounds. We further argue that they do not contain a massive graviton, nor the Boulware-Deser ghost. The model thus propagates only one graviton, whereas the nature of the additional degrees of freedom remains to be investigated. We also present a foliation-preserving deformation of the model, which keeps all symmetries except time diffeomorphisms and has three degrees of freedom.
Commentaires: 29 pages
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Dualities, DT invariants and higher depth mock modular forms
Auteur(s): Alexandrov S.
(Séminaires)
Mathematical Institute of University of Cologne (Cologne, DE), 2018-07-24
Résumé: Using dualities of string theory, I derive modular constraints onthe generating function of MSW invariants, which coincide withgeneralized Donaldson-Thomas invariants of a Calabi-Yau threefoldat the large volume attractor point in the moduli space. Thefunction is labeled by a divisor and when the divisor isirreducible, it is known to be modular. I show that in the case ofa reducible divisor, the modularity is lost, but can be restored
in a non-holomorphic completion. I find a general form of thecompletion for arbitrary degree of reducibility and provide its explicit expression up to degree 5.
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Dualities, DT invariants and higher depth mock modular forms
Auteur(s): Alexandrov S.
(Séminaires)
Max Planck Institute (Bonn, DE), 2018-07-23
Résumé: Using dualities of string theory, I derive modular constraints onthe generating function of MSW invariants, which coincide withgeneralized Donaldson-Thomas invariants of a Calabi-Yau threefoldat the large volume attractor point in the moduli space. Thefunction is labeled by a divisor and when the divisor isirreducible, it is known to be modular. I show that in the case ofa reducible divisor, the modularity is lost, but can be restored
in a non-holomorphic completion. I find a general form of thecompletion for arbitrary degree of reducibility and provide its explicit expression up to degree 5.
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BPS black holes, wall-crossing and mock modularity of higher depth
Auteur(s): Alexandrov S.
Conférence invité: Moonshine (Vienne, AT, 2018-09-10)
Ref HAL: hal-01875307_v1
Exporter : BibTex | endNote
Résumé: A class of BPS solutions in N=2 supergravity describes multi-centered black holes. Generically, they are stable only in a chamber of the moduli space so that the BPS index, counting these solutions, jumps across walls of marginal stability. I'll show how the attractor flow conjecture allows to express this index in terms of "attractor degeneracies" counting black holes at theattractor point. Besides, using duality constraints from string theory, I predict the behavior of the generating function of these degeneracies under modular transformations, which connects it to the theory of mock modular forms.
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Black holes and higher depth mock modular forms
Auteur(s): Alexandrov S., Pioline Boris
(Article) Publié:
Communications In Mathematical Physics, vol. 374 p.549–625 (2019)
Texte intégral en Openaccess :
Ref HAL: hal-01852413_v2
Ref Arxiv: 1808.08479
DOI: 10.1007/s00220-019-03609-y
WoS: 000527910200005
Ref. & Cit.: NASA ADS
Exporter : BibTex | endNote
Résumé: By enforcing invariance under S-duality in type IIB string theory compactified on a Calabi-Yau threefold, we derive modular properties of the generating function of BPS degeneracies of D4-D2-D0 black holes in type IIA string theory compactified on the same space.Mathematically, these BPS degeneracies are the generalized Donaldson-Thomas invariants counting coherent sheaves with support on a divisor$\cal D$ , at the large volume attractor point. For $\cal D$ irreducible, this function is closely related to the elliptic genus of the superconformal field theory obtained by wrapping M5-brane on $\cal D$ and is therefore known to be modular. Instead, when $\cal D$ is the sum of $n$ irreducible divisors ${\cal D}_i$, we show that the generating function acquires a modular anomaly. We characterize this anomaly for arbitrary $n$ by providing an explicit expression for a non-holomorphic modular completion in terms of generalized error functions. As a result, the generating function turns out to be a (mixed) mock modular form of depth $n−1$.
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BPS black holes, wall-crossing and modularity
Auteur(s): Alexandrov S.
Conference: Fifteenth Marcel Grossmann Meeting - MG15 (Rome, IT, 2018-07-01)
Ref HAL: hal-01852407_v1
Exporter : BibTex | endNote
Résumé: A class of BPS solutions in N=2 supergravity describes multi-centered black holes. Generically, they are stable only in a chamber of the moduli space so that the BPS index, counting these solutions, jumps across walls of marginal stability. I'll show how the attractor flow conjecture allows to express this index in terms of "attractor degeneracies" counting black holes at theattractor point. Besides, using duality constraints from string theory, I predict the behavior of the generating function of these degeneracies under modular transformations, which connects it to the theory of mock modular forms.
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Attractor flow trees, BPS indices and quivers
Auteur(s): Alexandrov S., Pioline Boris
(Article) Publié:
-Adv.theor.math.phys., vol. 23 p.627-699 (2019)
Texte intégral en Openaccess :
Ref HAL: hal-01781942_v1
Ref Arxiv: 1804.06928
Ref INSPIRE: 1668938
DOI: 10.4310/ATMP.2019.v23.n3.a2
Ref. & Cit.: NASA ADS
Exporter : BibTex | endNote
Résumé: Inspired by the split attractor flow conjecture for multi-centered black hole solutions in $N = 2$ supergravity, we propose a formula expressing the BPS index $\Omega (\gamma , z)$ in terms of ‘attractor indices’ $\Omega_{\ast} (\gamma_i)$. The latter count BPS states in their respective attractor chamber. This formula expresses the index as a sum over stable flow trees weighted by products of attractor indices. We show how to compute the contribution of each tree directly in terms of asymptotic data, without having to integrate the attractor flow explicitly. Furthermore, we derive new representations for the index which make it manifest that discontinuities associated to distinct trees cancel in the sum, leaving only the discontinuities consistent with wall-crossing. We apply these results in the context of quiver quantum mechanics, providing a new way of computing the Betti numbers of quiver moduli spaces, and compare them with the Coulomb branch formula, clarifying the relation between attractor and single-centered indices.
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