Dynamics and constraints of the massive graviton dark matter flat cosmologies
We discuss the dynamics of the Universe within the framework of the massive graviton cold dark matter scenario (MGCDM) in which gravitons are geometrically treated as massive particles. In this modified gravity theory, the main effect of the gravitons is to alter the density evolution of the cold da...
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| description | We discuss the dynamics of the Universe within the framework of the massive graviton cold dark matter scenario (MGCDM) in which gravitons are geometrically treated as massive particles. In this modified gravity theory, the main effect of the gravitons is to alter the density evolution of the cold dark matter component in such a way that the Universe evolves to an accelerating expanding regime, as presently observed. Tight constraints on the main cosmological parameters of the MGCDM model are derived by performing a joint likelihood analysis involving the recent supernovae type Ia data, the cosmic microwave background shift parameter, and the baryonic acoustic oscillations as traced by the Sloan Digital Sky Survey red luminous galaxies. The linear evolution of small density fluctuations is also analyzed in detail. It is found that the growth factor of the MGCDM model is slightly different ({approx}1-4%) from the one provided by the conventional flat {Lambda}CDM cosmology. The growth rate of clustering predicted by MGCDM and {Lambda}CDM models are confronted to the observations and the corresponding best fit values of the growth index ({gamma}) are also determined. By using the expectations of realistic future x-ray and Sunyaev-Zeldovich cluster surveys we derive the dark matter halo mass function and the corresponding redshift distribution of cluster-size halos for the MGCDM model. Finally, we also show that the Hubble flow differences between the MGCDM and the {Lambda}CDM models provide a halo redshift distribution departing significantly from the those predicted by other dark energy models. These results suggest that the MGCDM model can observationally be distinguished from {Lambda}CDM and also from a large number of dark energy models recently proposed in the literature. |
| doi_str_mv | 10.1103/PhysRevD.83.103506 |
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E. S. ; Lima, J. A. S.</creator><creatorcontrib>Basilakos, S. ; Plionis, M. ; Alves, M. E. S. ; Lima, J. A. S.</creatorcontrib><description>We discuss the dynamics of the Universe within the framework of the massive graviton cold dark matter scenario (MGCDM) in which gravitons are geometrically treated as massive particles. In this modified gravity theory, the main effect of the gravitons is to alter the density evolution of the cold dark matter component in such a way that the Universe evolves to an accelerating expanding regime, as presently observed. Tight constraints on the main cosmological parameters of the MGCDM model are derived by performing a joint likelihood analysis involving the recent supernovae type Ia data, the cosmic microwave background shift parameter, and the baryonic acoustic oscillations as traced by the Sloan Digital Sky Survey red luminous galaxies. The linear evolution of small density fluctuations is also analyzed in detail. It is found that the growth factor of the MGCDM model is slightly different ({approx}1-4%) from the one provided by the conventional flat {Lambda}CDM cosmology. The growth rate of clustering predicted by MGCDM and {Lambda}CDM models are confronted to the observations and the corresponding best fit values of the growth index ({gamma}) are also determined. By using the expectations of realistic future x-ray and Sunyaev-Zeldovich cluster surveys we derive the dark matter halo mass function and the corresponding redshift distribution of cluster-size halos for the MGCDM model. Finally, we also show that the Hubble flow differences between the MGCDM and the {Lambda}CDM models provide a halo redshift distribution departing significantly from the those predicted by other dark energy models. 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S.</creatorcontrib><title>Dynamics and constraints of the massive graviton dark matter flat cosmologies</title><title>Physical review. D, Particles and fields</title><description>We discuss the dynamics of the Universe within the framework of the massive graviton cold dark matter scenario (MGCDM) in which gravitons are geometrically treated as massive particles. In this modified gravity theory, the main effect of the gravitons is to alter the density evolution of the cold dark matter component in such a way that the Universe evolves to an accelerating expanding regime, as presently observed. Tight constraints on the main cosmological parameters of the MGCDM model are derived by performing a joint likelihood analysis involving the recent supernovae type Ia data, the cosmic microwave background shift parameter, and the baryonic acoustic oscillations as traced by the Sloan Digital Sky Survey red luminous galaxies. The linear evolution of small density fluctuations is also analyzed in detail. It is found that the growth factor of the MGCDM model is slightly different ({approx}1-4%) from the one provided by the conventional flat {Lambda}CDM cosmology. The growth rate of clustering predicted by MGCDM and {Lambda}CDM models are confronted to the observations and the corresponding best fit values of the growth index ({gamma}) are also determined. By using the expectations of realistic future x-ray and Sunyaev-Zeldovich cluster surveys we derive the dark matter halo mass function and the corresponding redshift distribution of cluster-size halos for the MGCDM model. Finally, we also show that the Hubble flow differences between the MGCDM and the {Lambda}CDM models provide a halo redshift distribution departing significantly from the those predicted by other dark energy models. These results suggest that the MGCDM model can observationally be distinguished from {Lambda}CDM and also from a large number of dark energy models recently proposed in the literature.</description><subject>ASTROPHYSICS, COSMOLOGY AND ASTRONOMY</subject><subject>BARYONS</subject><subject>BINARY STARS</subject><subject>COSMOLOGY</subject><subject>DENSITY</subject><subject>DISTRIBUTION</subject><subject>ELECTROMAGNETIC RADIATION</subject><subject>ELEMENTARY PARTICLES</subject><subject>ERUPTIVE VARIABLE STARS</subject><subject>EVOLUTION</subject><subject>FERMIONS</subject><subject>FIELD THEORIES</subject><subject>FLUCTUATIONS</subject><subject>GALAXIES</subject><subject>GRAVITATION</subject><subject>GRAVITATIONAL RADIATION</subject><subject>GRAVITONS</subject><subject>GROWTH FACTORS</subject><subject>HADRONS</subject><subject>IONIZING RADIATIONS</subject><subject>MASS</subject><subject>MASSLESS PARTICLES</subject><subject>MATTER</subject><subject>MICROWAVE RADIATION</subject><subject>MITOGENS</subject><subject>NONLUMINOUS MATTER</subject><subject>ORGANIC COMPOUNDS</subject><subject>OSCILLATIONS</subject><subject>PARTICLES</subject><subject>PHYSICAL PROPERTIES</subject><subject>PHYSICS OF ELEMENTARY PARTICLES AND FIELDS</subject><subject>POSTULATED PARTICLES</subject><subject>PROTEINS</subject><subject>QUANTUM FIELD THEORY</subject><subject>QUANTUM GRAVITY</subject><subject>RADIATIONS</subject><subject>RED SHIFT</subject><subject>RELICT RADIATION</subject><subject>STARS</subject><subject>SUPERNOVAE</subject><subject>UNIVERSE</subject><subject>VARIABLE STARS</subject><subject>VARIATIONS</subject><subject>X RADIATION</subject><issn>1550-7998</issn><issn>0556-2821</issn><issn>1550-2368</issn><issn>1089-4918</issn><fulltext>true</fulltext><rsrctype>article</rsrctype><creationdate>2011</creationdate><recordtype>article</recordtype><recordid>eNo1kE1LAzEQhoMoWKt_wFPA89Yk02SzR2n9gooieg7ZbNJGuxvJhEL_vSutp_ngmeHlIeSasxnnDG7fNnt897vlTMNsnCVTJ2TCpWSVAKVPj33dNPqcXCB-MQZC1fWEvCz3g-2jQ2qHjro0YMk2DgVpCrRsPO0tYtx5us52F0saaGfz97gtxWcatraMR9inbVpHj5fkLNgt-qtjnZLPh_uPxVO1en18XtytKidqWapaAdRQd03DeAhKKqbboLvQQeiCAOl8o7TtghOOtWNmANU64DBi81ZbBVNyc_ibsESDLhbvNmP4wbtiBJdMyHkzUuJAuZwQsw_mJ8fe5r3hzPxpM__ajAZz0Aa_oXljBw</recordid><startdate>20110504</startdate><enddate>20110504</enddate><creator>Basilakos, S.</creator><creator>Plionis, M.</creator><creator>Alves, M. E. S.</creator><creator>Lima, J. A. S.</creator><scope>AAYXX</scope><scope>CITATION</scope><scope>OTOTI</scope></search><sort><creationdate>20110504</creationdate><title>Dynamics and constraints of the massive graviton dark matter flat cosmologies</title><author>Basilakos, S. ; Plionis, M. ; Alves, M. E. S. ; Lima, J. A. S.</author></sort><facets><frbrtype>5</frbrtype><frbrgroupid>cdi_FETCH-LOGICAL-c275t-7633737d9901ff65608bf8dfd3fdf235ce968adfc2c0b998336bc31308b4b8a63</frbrgroupid><rsrctype>articles</rsrctype><prefilter>articles</prefilter><language>eng</language><creationdate>2011</creationdate><topic>ASTROPHYSICS, COSMOLOGY AND ASTRONOMY</topic><topic>BARYONS</topic><topic>BINARY STARS</topic><topic>COSMOLOGY</topic><topic>DENSITY</topic><topic>DISTRIBUTION</topic><topic>ELECTROMAGNETIC RADIATION</topic><topic>ELEMENTARY PARTICLES</topic><topic>ERUPTIVE VARIABLE STARS</topic><topic>EVOLUTION</topic><topic>FERMIONS</topic><topic>FIELD THEORIES</topic><topic>FLUCTUATIONS</topic><topic>GALAXIES</topic><topic>GRAVITATION</topic><topic>GRAVITATIONAL RADIATION</topic><topic>GRAVITONS</topic><topic>GROWTH FACTORS</topic><topic>HADRONS</topic><topic>IONIZING RADIATIONS</topic><topic>MASS</topic><topic>MASSLESS PARTICLES</topic><topic>MATTER</topic><topic>MICROWAVE RADIATION</topic><topic>MITOGENS</topic><topic>NONLUMINOUS MATTER</topic><topic>ORGANIC COMPOUNDS</topic><topic>OSCILLATIONS</topic><topic>PARTICLES</topic><topic>PHYSICAL PROPERTIES</topic><topic>PHYSICS OF ELEMENTARY PARTICLES AND FIELDS</topic><topic>POSTULATED PARTICLES</topic><topic>PROTEINS</topic><topic>QUANTUM FIELD THEORY</topic><topic>QUANTUM GRAVITY</topic><topic>RADIATIONS</topic><topic>RED SHIFT</topic><topic>RELICT RADIATION</topic><topic>STARS</topic><topic>SUPERNOVAE</topic><topic>UNIVERSE</topic><topic>VARIABLE STARS</topic><topic>VARIATIONS</topic><topic>X RADIATION</topic><toplevel>peer_reviewed</toplevel><toplevel>online_resources</toplevel><creatorcontrib>Basilakos, S.</creatorcontrib><creatorcontrib>Plionis, M.</creatorcontrib><creatorcontrib>Alves, M. E. S.</creatorcontrib><creatorcontrib>Lima, J. A. S.</creatorcontrib><collection>CrossRef</collection><collection>OSTI.GOV</collection><jtitle>Physical review. D, Particles and fields</jtitle></facets><delivery><delcategory>Remote Search Resource</delcategory><fulltext>fulltext</fulltext></delivery><addata><au>Basilakos, S.</au><au>Plionis, M.</au><au>Alves, M. E. S.</au><au>Lima, J. A. S.</au><format>journal</format><genre>article</genre><ristype>JOUR</ristype><atitle>Dynamics and constraints of the massive graviton dark matter flat cosmologies</atitle><jtitle>Physical review. D, Particles and fields</jtitle><date>2011-05-04</date><risdate>2011</risdate><volume>83</volume><issue>10</issue><artnum>103506</artnum><issn>1550-7998</issn><issn>0556-2821</issn><eissn>1550-2368</eissn><eissn>1089-4918</eissn><abstract>We discuss the dynamics of the Universe within the framework of the massive graviton cold dark matter scenario (MGCDM) in which gravitons are geometrically treated as massive particles. In this modified gravity theory, the main effect of the gravitons is to alter the density evolution of the cold dark matter component in such a way that the Universe evolves to an accelerating expanding regime, as presently observed. Tight constraints on the main cosmological parameters of the MGCDM model are derived by performing a joint likelihood analysis involving the recent supernovae type Ia data, the cosmic microwave background shift parameter, and the baryonic acoustic oscillations as traced by the Sloan Digital Sky Survey red luminous galaxies. The linear evolution of small density fluctuations is also analyzed in detail. It is found that the growth factor of the MGCDM model is slightly different ({approx}1-4%) from the one provided by the conventional flat {Lambda}CDM cosmology. The growth rate of clustering predicted by MGCDM and {Lambda}CDM models are confronted to the observations and the corresponding best fit values of the growth index ({gamma}) are also determined. By using the expectations of realistic future x-ray and Sunyaev-Zeldovich cluster surveys we derive the dark matter halo mass function and the corresponding redshift distribution of cluster-size halos for the MGCDM model. Finally, we also show that the Hubble flow differences between the MGCDM and the {Lambda}CDM models provide a halo redshift distribution departing significantly from the those predicted by other dark energy models. These results suggest that the MGCDM model can observationally be distinguished from {Lambda}CDM and also from a large number of dark energy models recently proposed in the literature.</abstract><cop>United States</cop><doi>10.1103/PhysRevD.83.103506</doi></addata></record> |
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| subjects | ASTROPHYSICS, COSMOLOGY AND ASTRONOMY BARYONS BINARY STARS COSMOLOGY DENSITY DISTRIBUTION ELECTROMAGNETIC RADIATION ELEMENTARY PARTICLES ERUPTIVE VARIABLE STARS EVOLUTION FERMIONS FIELD THEORIES FLUCTUATIONS GALAXIES GRAVITATION GRAVITATIONAL RADIATION GRAVITONS GROWTH FACTORS HADRONS IONIZING RADIATIONS MASS MASSLESS PARTICLES MATTER MICROWAVE RADIATION MITOGENS NONLUMINOUS MATTER ORGANIC COMPOUNDS OSCILLATIONS PARTICLES PHYSICAL PROPERTIES PHYSICS OF ELEMENTARY PARTICLES AND FIELDS POSTULATED PARTICLES PROTEINS QUANTUM FIELD THEORY QUANTUM GRAVITY RADIATIONS RED SHIFT RELICT RADIATION STARS SUPERNOVAE UNIVERSE VARIABLE STARS VARIATIONS X RADIATION |
| title | Dynamics and constraints of the massive graviton dark matter flat cosmologies |
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