Yashar Akrami Modern Cosmology: Early Universe, CMB and LSS/ Benasque/ August 17, 2012 Postdoctoral Fellow Institute of Theoretical Astrophysics University.

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Presentation transcript:

Yashar Akrami Modern Cosmology: Early Universe, CMB and LSS/ Benasque/ August 17, 2012 Postdoctoral Fellow Institute of Theoretical Astrophysics University of Oslo, Norway (Hans Kristian Eriksen, David Mota) with: Tomi S. Koivisto & Marit Sandstad [arXiv:1208.xxxx] C osmic A cceleration from G host-free, M assive Bi G ravity: A Statistical Analysis with Improved Generality

Yashar Akrami / Modern Cosmology: Early Universe, CMB and LSS/ Benasque / August 17, Late-time Acceleration Motivation 2011 Nobel Prize in Physics “…for the discovery of the accelerating expansion of the Universe through observations of distant supernovae” Saul Perlmutter Brian P. Schmidt Adam G. Riess +1 too big: CC problem =0 - Symmetry - Degravitation, - …

Yashar Akrami / Modern Cosmology: Early Universe, CMB and LSS/ Benasque / August 17, Motivation +1 Dark Energy or Modified Gravity Example: Scalar Fields: [Luca’s talk] The most general 4D scalar field theory with second order equation of motion: Horndeski Lagrangian Any Alternatives?

Fierz & Pauli (1939): Demand for Massive Gravity +1 Yashar Akrami / Modern Cosmology: Early Universe, CMB and LSS/ Benasque / August 17, The only ghost-free mass term: (linearized metric fluctuations around flat space-time) Consistent Non-linear Completion? Theoretically challenging, cosmologically interesting. 2011: breakthrough de Rham & Gabadadze[arXiv: ] de Rham, Gabadadze & Tolley[arXiv: ] Hassan & Rosen[arXiv: ] [arXiv: ] [arXiv: ] [arXiv: ] Hassan, Rosen & Schmidt-May[arXiv: ] The only ghost-free, massive gravity The only ghost-free, bimetric gravity

Action: Theory (general) Hassan-Rosen bimetric gravity based on de-Rham-Gabadadze-Tolley massive gravity: +1 Yashar Akrami / Modern Cosmology: Early Universe, CMB and LSS/ Benasque / August 17,

Equations of Motion: Theory (general) Bianchi Identities + Energy-Momentum Conservation : +1 Yashar Akrami / Modern Cosmology: Early Universe, CMB and LSS/ Benasque / August 17,

Metrics: Theory (the case for an isotropic and homogeneous universe) Bianchi Identities + Energy-Momentum Conservation: +1 Yashar Akrami / Modern Cosmology: Early Universe, CMB and LSS/ Benasque / August 17,

Generalized Friedmann Equations: Theory (the case for an isotropic and homogeneous universe) +1 Yashar Akrami / Modern Cosmology: Early Universe, CMB and LSS/ Benasque / August 17,

Theory (the case for an isotropic and homogeneous universe) Evolution Equation: Hubble Parameter: +1 Yashar Akrami / Modern Cosmology: Early Universe, CMB and LSS/ Benasque / August 17, Initial Conditions: one-dimensional phase space

Observational Constraints: Scanning Method: Model Parameter: B 0, B 1, B 2, B 3, B 4, Ω m 0 (no Ω ϒ, no curvature ) (B 0 =0) State-of-the-art scanning algorithm: MultiNest (nested sampling): MCMC-like (both Bayesian and frequentist statistics) +1 Yashar Akrami / Modern Cosmology: Early Universe, CMB and LSS/ Benasque / August 17, D L, D V, D A, H(z)Data: 1. Luminosity distances from Type Ia SNe: 580 points (Union 2.1) 2. Position of the 1 st CMB power-spectrum peak (angular scale of sound horizon at recombination era): 1 point (WMAP 7) 3. BAO: Ratio of sound horizon scale at drag epoch to dilation scale: 6 points (2dFGRS, 6dFGS, SDSS and WiggleZ) 4. Constraints on H 0 : 1 point (purely background)

Some Results: Minimal Non-linear Extension of Massive Fierz-Pauli Action without CC: B 1, Ω m 0 : Best-fit χ 2 : P-value: Log-Evidence: Best-fit χ 2 : P-value: Log-Evidence: Λ CDM: both consistent with the data (less than 1 σ deviation) +1 Yashar Akrami / Modern Cosmology: Early Universe, CMB and LSS/ Benasque / August 17,

Some Results: (B 1, Ω m 0 ) +1 Yashar Akrami / Modern Cosmology: Early Universe, CMB and LSS/ Benasque / August 17, Independent of Priors

Some Results: (B 1, Ω m 0 ) Graviton Mass: m 2 = 1.45 H 0 2 ± 0.25 H 0 2 Independent of Priors +1 Yashar Akrami / Modern Cosmology: Early Universe, CMB and LSS/ Benasque / August 17,

Some Results: (B 1, Ω m 0 ) +1 Yashar Akrami / Modern Cosmology: Early Universe, CMB and LSS/ Benasque / August 17,

Some Results: (B 1, Ω m 0 ) +1 Yashar Akrami / Modern Cosmology: Early Universe, CMB and LSS/ Benasque / August 17, Ω Λ = B 1 y

Some Results: B 2, Ω m 0 Best-fit χ 2 : P-value: < Log-Evidence: considered to be extremely statistically significant Excluded! B 3, Ω m 0 Best-fit χ 2 : P-value: < Log-Evidence: Yashar Akrami / Modern Cosmology: Early Universe, CMB and LSS/ Benasque / August 17,

Some Results: B 1, B 2, Ω m 0 Best-fit χ 2 : P-value: Log-Evidence: consistent with the data within 1 σ B 1, B 3, Ω m 0 Best-fit χ 2 : P-value: Log-Evidence: B 2, B 3, Ω m 0 Best-fit χ 2 : P-value: Log-Evidence: Yashar Akrami / Modern Cosmology: Early Universe, CMB and LSS/ Benasque / August 17, { for (B 1, Ω m ) & for Λ CDM} { for (B 1, Ω m ) & for Λ CDM} complexity of the model increases considerably when we increase the number of model parameters

Some Results: (B 1, B 2, Ω m 0 ) Yashar Akrami / Modern Cosmology: Early Universe, CMB and LSS/ Benasque / August 17, Enlarged prior ranges:

Some Results: (B 1, B 2, Ω m 0 ) +1 Yashar Akrami / Modern Cosmology: Early Universe, CMB and LSS/ Benasque / August 17, Enlarged prior ranges:

Some Results: (B 1, B 2, Ω m 0 ) +1 Yashar Akrami / Modern Cosmology: Early Universe, CMB and LSS/ Benasque / August 17, Enlarged prior ranges:

Some Results: (B 1, B 2, Ω m 0 ) +1 Yashar Akrami / Modern Cosmology: Early Universe, CMB and LSS/ Benasque / August 17, Enlarged prior ranges:

Some Results: (B 1, B 2, Ω m 0 ) +1 Yashar Akrami / Modern Cosmology: Early Universe, CMB and LSS/ Benasque / August 17,

① A comprehensive statistical analysis of Hassan-Rosen ghost- free, massive, bimetric gravity (for cosmology at background level) + several analytical explanations of results, ② Massive gravity can give “Accelerated Expansion” with no explicit Cosmological Constant, ③ Very good fit even in the 1-parameter case, ④ Parameters are correlated for the full model, ⑤ Background data are not enough to constrain the full model (not robust and prior-independent), ⑥ Analysis of perturbations and other astrophysical probes needed to break degeneracy and constrain the model, ⑦ Further theoretical generalizations, e.g. curvature, coupling of “f” to matter, other background metrics, etc. Summary & Conclusions +1 Yashar Akrami / Modern Cosmology: Early Universe, CMB and LSS/ Benasque / August 17,

for your attention