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Constraining graviton non-Gaussianity through the CMB bispectra
Tensor non-Gaussianities are a key ingredient to test the symmetries and the presence of higher spin fields during the inflationary epoch. Indeed, the shape of the three point correlator of the graviton is totally fixed by the symmetries of the de Sitter stage and, in the case of parity conservation...
| Autores principales: | , , , , |
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| Lenguaje: | eng |
| Publicado: |
2019
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| Materias: | |
| Acceso en línea: | https://dx.doi.org/10.1103/PhysRevD.100.063535 http://cds.cern.ch/record/2691258 |
| _version_ | 1780963808536166400 |
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| author | De Luca, Valerio Franciolini, Gabriele Kehagias, Alex Riotto, Antonio Shiraishi, Maresuke |
| author_facet | De Luca, Valerio Franciolini, Gabriele Kehagias, Alex Riotto, Antonio Shiraishi, Maresuke |
| author_sort | De Luca, Valerio |
| collection | CERN |
| description | Tensor non-Gaussianities are a key ingredient to test the symmetries and the presence of higher spin fields during the inflationary epoch. Indeed, the shape of the three point correlator of the graviton is totally fixed by the symmetries of the de Sitter stage and, in the case of parity conservation, gets contributions only from the ordinary gravity action plus a higher derivative term called the (Weyl)3 action. We discuss current and future bounds on the three point tensor contribution from the (Weyl)3 term using cosmic microwave background (CMB) bispectra. Our results indicate that forthcoming experiments, such as LiteBIRD, CMB-S4, and CORE, will detect the presence of the (Weyl)3 term if Mp4L4∼1017r-4, where L parametrizes the strength of the (Weyl)3 term and r is the tensor-to-scalar ratio, which corresponds to L≳3.2×105Mp-1, while the current upper limit is Mp4L4=(1.1±4.0)×1019r-4 (68% CL). |
| id | cern-2691258 |
| institution | Organización Europea para la Investigación Nuclear |
| language | eng |
| publishDate | 2019 |
| record_format | invenio |
| spelling | cern-26912582023-03-14T17:21:22Zdoi:10.1103/PhysRevD.100.063535http://cds.cern.ch/record/2691258engDe Luca, ValerioFranciolini, GabrieleKehagias, AlexRiotto, AntonioShiraishi, MaresukeConstraining graviton non-Gaussianity through the CMB bispectrahep-phParticle Physics - Phenomenologygr-qcGeneral Relativity and Cosmologyastro-ph.COAstrophysics and AstronomyTensor non-Gaussianities are a key ingredient to test the symmetries and the presence of higher spin fields during the inflationary epoch. Indeed, the shape of the three point correlator of the graviton is totally fixed by the symmetries of the de Sitter stage and, in the case of parity conservation, gets contributions only from the ordinary gravity action plus a higher derivative term called the (Weyl)3 action. We discuss current and future bounds on the three point tensor contribution from the (Weyl)3 term using cosmic microwave background (CMB) bispectra. Our results indicate that forthcoming experiments, such as LiteBIRD, CMB-S4, and CORE, will detect the presence of the (Weyl)3 term if Mp4L4∼1017r-4, where L parametrizes the strength of the (Weyl)3 term and r is the tensor-to-scalar ratio, which corresponds to L≳3.2×105Mp-1, while the current upper limit is Mp4L4=(1.1±4.0)×1019r-4 (68% CL).Tensor non-Gaussianities are a key ingredient to test the symmetries and the presence of higher spin fields during the inflationary epoch. Indeed, the shape of the three point correlator of the graviton is totally fixed by the symmetries of the de Sitter stage and, in the case of parity conservation, gets contributions only from the ordinary gravity action plus a higher derivative term called the (Weyl)$^3$ action. We discuss current and future bounds on the three point tensor contribution from the (Weyl)$^3$ term using cosmic microwave background (CMB) bispectra. Our results indicate that forthcoming experiments, such as LiteBIRD, CMB-S4 and CORE, will detect the presence of the (Weyl)$^3$ term if $M_p^4 L^4 \sim 10^{17} r^{-4}$, where $L$ parametrizes the strength of the (Weyl)$^3$ term and $r$ is the tensor-to-scalar ratio, which corresponds to $L\gtrsim 3.2 \times 10^5 M_p^{-1}$, while the current upper limit is $M_p^4 L^4 = (1.1 \pm 4.0) \times 10^{19} r^{-4}$ (68%CL).arXiv:1908.00366oai:cds.cern.ch:26912582019-08-01 |
| spellingShingle | hep-ph Particle Physics - Phenomenology gr-qc General Relativity and Cosmology astro-ph.CO Astrophysics and Astronomy De Luca, Valerio Franciolini, Gabriele Kehagias, Alex Riotto, Antonio Shiraishi, Maresuke Constraining graviton non-Gaussianity through the CMB bispectra |
| title | Constraining graviton non-Gaussianity through the CMB bispectra |
| title_full | Constraining graviton non-Gaussianity through the CMB bispectra |
| title_fullStr | Constraining graviton non-Gaussianity through the CMB bispectra |
| title_full_unstemmed | Constraining graviton non-Gaussianity through the CMB bispectra |
| title_short | Constraining graviton non-Gaussianity through the CMB bispectra |
| title_sort | constraining graviton non-gaussianity through the cmb bispectra |
| topic | hep-ph Particle Physics - Phenomenology gr-qc General Relativity and Cosmology astro-ph.CO Astrophysics and Astronomy |
| url | https://dx.doi.org/10.1103/PhysRevD.100.063535 http://cds.cern.ch/record/2691258 |
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