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Completing Lorentz violating massive gravity at high energies
Theories with massive gravitons are interesting for a variety of physical applications, ranging from cosmological phenomena to holographic modeling of condensed matter systems. To date, they have been formulated as effective field theories with a cutoff proportional to a positive power of the gravit...
| Autores principales: | , |
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| Lenguaje: | eng |
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2014
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| Acceso en línea: | https://dx.doi.org/10.1134/S1063776115030164 https://dx.doi.org/10.7868/S0044451015030180 http://cds.cern.ch/record/1954361 |
| _version_ | 1780944412523626496 |
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| author | Blas, Diego Sibiryakov, Sergey |
| author_facet | Blas, Diego Sibiryakov, Sergey |
| author_sort | Blas, Diego |
| collection | CERN |
| description | Theories with massive gravitons are interesting for a variety of physical applications, ranging from cosmological phenomena to holographic modeling of condensed matter systems. To date, they have been formulated as effective field theories with a cutoff proportional to a positive power of the graviton mass m_g and much smaller than that of the massless theory (M_P ~ 10^19 GeV in the case of general relativity). In this paper we present an ultraviolet completion for massive gravity valid up to a high energy scale independent of the graviton mass. The construction is based on the existence of a preferred time foliation combined with spontaneous condensation of vector fields. The perturbations of these fields are massive and below their mass the theory reduces to a model of Lorentz violating massive gravity. The latter theory possesses instantaneous modes whose consistent quantization we discuss in detail. We briefly study some modifications to gravitational phenomenology at low-energies. The homogeneous cosmological solutions are the same as in the standard cosmology. The gravitational potential of point sources agrees with the Newtonian one at distances small with respect to m_g^(-1). Interestingly, it becomes repulsive at larger distances. |
| id | cern-1954361 |
| institution | Organización Europea para la Investigación Nuclear |
| language | eng |
| publishDate | 2014 |
| record_format | invenio |
| spelling | cern-19543612023-01-26T08:06:44Zdoi:10.1134/S1063776115030164doi:10.7868/S0044451015030180http://cds.cern.ch/record/1954361engBlas, DiegoSibiryakov, SergeyCompleting Lorentz violating massive gravity at high energiesParticle Physics - TheoryTheories with massive gravitons are interesting for a variety of physical applications, ranging from cosmological phenomena to holographic modeling of condensed matter systems. To date, they have been formulated as effective field theories with a cutoff proportional to a positive power of the graviton mass m_g and much smaller than that of the massless theory (M_P ~ 10^19 GeV in the case of general relativity). In this paper we present an ultraviolet completion for massive gravity valid up to a high energy scale independent of the graviton mass. The construction is based on the existence of a preferred time foliation combined with spontaneous condensation of vector fields. The perturbations of these fields are massive and below their mass the theory reduces to a model of Lorentz violating massive gravity. The latter theory possesses instantaneous modes whose consistent quantization we discuss in detail. We briefly study some modifications to gravitational phenomenology at low-energies. The homogeneous cosmological solutions are the same as in the standard cosmology. The gravitational potential of point sources agrees with the Newtonian one at distances small with respect to m_g^(-1). Interestingly, it becomes repulsive at larger distances.Theories with massive gravitons are interesting for a variety of physical applications, ranging from cosmological phenomena to holographic modeling of condensed matter systems. To date, they have been formulated as effective field theories with a cutoff proportional to a positive power of the graviton mass m$_{g}$ and much smaller than that of the massless theory (M$_{P}$ ≈ 10$^{19}$ GeV in the case of general relativity). In this paper, we present an ultraviolet completion for massive gravity valid up to a high energy scale independent of the graviton mass. The construction is based on the existence of a preferred time foliation combined with spontaneous condensation of vector fields. The perturbations of these fields are massive and below their mass, the theory reduces to a model of Lorentz violating massive gravity. The latter theory possesses instantaneous modes whose consistent quantization we discuss in detail. We briefly study some modifications to gravitational phenomenology at low-energies. The homogeneous cosmological solutions are the same as in the standard cosmology. The gravitational potential of point sources agrees with the Newtonian one at distances small with respect to m$_{g}^{−1}$ . Interestingly, it becomes repulsive at larger distances.Theories with massive gravitons are interesting for a variety of physical applications, ranging from cosmological phenomena to holographic modeling of condensed matter systems. To date, they have been formulated as effective field theories with a cutoff proportional to a positive power of the graviton mass m_g and much smaller than that of the massless theory (M_P ~ 10^19 GeV in the case of general relativity). In this paper we present an ultraviolet completion for massive gravity valid up to a high energy scale independent of the graviton mass. The construction is based on the existence of a preferred time foliation combined with spontaneous condensation of vector fields. The perturbations of these fields are massive and below their mass the theory reduces to a model of Lorentz violating massive gravity. The latter theory possesses instantaneous modes whose consistent quantization we discuss in detail. We briefly study some modifications to gravitational phenomenology at low-energies. The homogeneous cosmological solutions are the same as in the standard cosmology. The gravitational potential of point sources agrees with the Newtonian one at distances small with respect to m_g^(-1). Interestingly, it becomes repulsive at larger distances.arXiv:1410.2408CERN-PH-TH-2014-191INR-TH-2014-021CERN-PH-TH-2014-191INR-TH-2014-021oai:cds.cern.ch:19543612014-10-09 |
| spellingShingle | Particle Physics - Theory Blas, Diego Sibiryakov, Sergey Completing Lorentz violating massive gravity at high energies |
| title | Completing Lorentz violating massive gravity at high energies |
| title_full | Completing Lorentz violating massive gravity at high energies |
| title_fullStr | Completing Lorentz violating massive gravity at high energies |
| title_full_unstemmed | Completing Lorentz violating massive gravity at high energies |
| title_short | Completing Lorentz violating massive gravity at high energies |
| title_sort | completing lorentz violating massive gravity at high energies |
| topic | Particle Physics - Theory |
| url | https://dx.doi.org/10.1134/S1063776115030164 https://dx.doi.org/10.7868/S0044451015030180 http://cds.cern.ch/record/1954361 |
| work_keys_str_mv | AT blasdiego completinglorentzviolatingmassivegravityathighenergies AT sibiryakovsergey completinglorentzviolatingmassivegravityathighenergies |