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Dark Energy Interactions, Nordita, October 3, 2014
Backreaction status report
Syksy Räsänen
University of HelsinkiDepartment of Physics andHelsinki Institute of Physics
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Dark Energy Interactions, Nordita, October 3, 2014
Looking for a factor of 2
The early universe is well described by a model which is homogeneous and isotropic, contains only ordinary matter and evolves according to ordinary general relativity.
In the late universe, such a model underpredicts distance and expansion rate by a factor of 2.
Three possibilities:1) There is matter with negative pressure.2) General relativity does not hold on cosmological scales.3) The homogeneous and isotropic approximation is not valid.
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Dark Energy Interactions, Nordita, October 3, 2014
Our clumpy universe
At late times, the universe is only statistically homogeneous and isotropic, on scales >100 Mpc.
The average evolution of a clumpy spacetime is not the same as the evolution of a smooth spacetime, a feature known as backreaction.
Structures affect expansion rate, light propagation and their relationship.
Backreaction conjecture: the reason for the failure of the homogeneous and isotropic models is the known breakdown of local homogeneity and isotropy.
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Dark Energy Interactions, Nordita, October 3, 2014
The Buchert equations (T. Buchert: gr-qc/9906015)
Here
The backreaction variable is
The average expansion can accelerate, even though the local expansion decelerates.
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Dark Energy Interactions, Nordita, October 3, 2014
Understanding acceleration
The average expansion rate can increase, because the fraction of volume taken by faster regions grows.
Structure formation involves overdense regions slowing down more and underdense regions decelerating less.
Acceleration can be demonstrated with a toy model which has one overdense and one underdense region. (SR: astro-ph/0607626)
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Dark Energy Interactions, Nordita, October 3, 2014
Scales of acceleration
The magnitude of the change in the expansion rate and the 10 billion year timing emerge from the physics of structure formation. (SR: 0801.2692)
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Dark Energy Interactions, Nordita, October 3, 2014
Homogeneity is not enough We can build a Swiss Cheese model where the average
expansion rate is different from the background, even though the holes are small and their distribution is H&I. (M. Lavinto, SR, S. Szybka: 1308.6731)
The average expansion rate rises at late times relative to the background.
Holes are ‘larger on the inside than the outside’: Tardis.
The average expansion rate describes the redshift and (with caveats) DA well.
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Dark Energy Interactions, Nordita, October 3, 2014 8
Dark Energy Interactions, Nordita, October 3, 2014
Light and space
The result probably generalises: H&I imply that z and DA
are determined by the average expansion rate. (SR:
0812.2872, 0912.3370, P. Bull, T. Clifton: 1203.4479)
For the angular diameter distance, we have (with )
Due to conservation of mass,
The distance in terms of H(z) is the same as in ΛCDM. If H(z) deviates from ΛCDM, the relation between H and
DA is different than in FRW. 9
Dark Energy Interactions, Nordita, October 3, 2014
Newtonian gravity
When density contrast becomes non-linear, variance of θ and shear become large.
In Newtonian gravity, is a boundary term. (T. Buchert, J. Ehlers: astro-ph/9510056)
In general relativity, variance and shear do not in general cancel.
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Dark Energy Interactions, Nordita, October 3, 2014
Perturbation theory
In perturbation theory, variance and shear are of the order .
If the metric perturbations around FRW and their first derivatives are small, variance and shear cancel, so and z are close to FRW. (SR: 1107.1176; see also S. Green, R. Wald: 1011.4920)
This is not true for DA in general. (K. Enqvist, M. Mattsson, G.
Rigopoulos: 0907.4003)
If the universe remains close to the same FRW metric everywhere, backreaction is small. (See J. Adamek et al: 1308.6524, 1408.2741, 1408.3352)
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Dark Energy Interactions, Nordita, October 3, 2014
Observations
Backreaction is indirectly constrained by the fact that ΛCDM fits well.
This does not mean that well-fitting models have to be close to ΛCDM.
Backreaction has a unique signature: deviation from the FRW distance-expansion rate relation. (C. Clarkson, B.A. Bassett, T. H.-C. Lu: 0712.3457)
Can be tested with observations of H(z)1, cosmic parallax (SR:
1312.5738) and strong lensing.1A. Shafieloo, C. Clarkson: 0911.4858, E. Mörtsell, J. Jönsson:1102.4485, D. Sapone, E. Majerotto, S. Nesseris: 1402.2236, A. Heavens, R. Jimenez, L. Verde: 1409.6217 12
Dark Energy Interactions, Nordita, October 3, 2014 13
C. Boehm, SR: 1305.7139
Dark Energy Interactions, Nordita, October 3, 2014
Observations
Backreaction is indirectly constrained by the fact that ΛCDM fits well.
This does not mean that well-fitting models have to be close to ΛCDM.
Backreaction has a unique signature: deviation from the FRW distance-expansion rate relation. (C. Clarkson, B.A. Bassett, T. H.-C. Lu: 0712.3457)
Can be tested with observations of H(z)1, cosmic parallax (SR:
1312.5738) and strong lensing.1A. Shafieloo, C. Clarkson: 0911.4858, E. Mörtsell, J. Jönsson:1102.4485, D. Sapone, E. Majerotto, S. Nesseris: 1402.2236, A. Heavens, R. Jimenez, L. Verde: 1409.6217 14
Dark Energy Interactions, Nordita, October 3, 2014
Summary Statistically homogeneous and isotropic spaces do not in
general expand like FRW.
Structure formation has a timescale of 1010 years.
Light propagation can be described by the average expansion rate.
If the universe is close to the same FRW metric everywhere, backreaction is small.
Even if backreaction is small, it can be important for precision measurements. (C. Clarkson et al: 1405.7860)
Backreaction can be tested by comparing distance and expansion rate.
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