CMB statistical anisotropy and the lensing bispectrum

Antony Lewis

http://cosmologist.info/

Lewis, Challinor & Hanson: in prep

Hanson & Lewis: 0908.0963 Hanson, Lewis & Challinor: 1003.0198

Hu & White, Sci. Am., 290 44 (2004)

Evolution of the universe

Opaque

Transparent

Source: NASA/WMAP Science Team

O(10-5) perturbations (+galaxy)

Dipole (local motion)

(almost) uniform 2.726K blackbody

Observations: the microwave sky today

Can we predict the primordial perturbations?

• Maybe..

Quantum Mechanics “waves in a box”

Inflation make >1030 times bigger

After inflation Huge size, amplitude ~ 10-5

CMB temperature

End of inflation Last scattering surface

gravity+ pressure+ diffusion

14 000 Mpc

z~1000

z=0 θ

Observed CMB temperature power spectrum

Observations Constrain theory of early universe + evolution parameters and geometry

Hinshaw et al.

The Vanilla Universe Assumptions

• Translation invariance - statistical homogeneity (observers see the same things on average after spatial translation)

• Rotational invariance - statistical isotropy (observations at a point the same under sky rotation on average)

• Primordial adiabatic nearly scale-invariant Gaussian fluctuations filling a flat universe

Statistically isotropic CMB with Gaussian fluctuations and smooth power spectrum

WMAP spice - not so vanilla?

Low quadrupole?

Alignments?

Quadrupole Octopole Tegmark et al.

WMAP team

Cruz et al, 0901.1986

Cold spot?

Power asymmetry?

+Non-Gaussianity?… +….? Eriksen et al, Hansen et al.

• CMB lensing

• Power asymmetries

• Anisotropic primordial power

• Spatially-modulated primordial power

• Non-Gaussianity

Gaussian statistical anisotropy

+ various systematics, anisotropic noise, beam effects, …

Gaussian anisotropic models

Or is it a statistically isotropic non-Gaussian model??

SH SH SH SH SH SH SH

Example: CMB lensing

Last scattering surface

Inhomogeneous universe - photons deflected

Observer

Gaussian LSS

Expected signal..

Unlensed Magnified Demagnified

For a given lensing field : 𝑇 ∼ 𝑃(𝑇|𝜓)

- Anisotropic Gaussian temperature distribution - Different parts of the sky magnified and demagnified - Re-construct the actual lensing field – infer 𝜓

Or marginalized over lensing fields:

𝑇 ∼ ∫ 𝑃(𝑇, 𝜓)𝑑𝜓

-Non-Gaussian statistically isotropic temperature distribution - Significant connected 4-point function - Excess variance to anisotropic-looking realizations - Lensed temperature power spectrum

Anisotropy estimators

Maximum likelihood:

First iteration solution: Quadratic Maximum Likelihood (QML)

Reconstruction recipe

Inverse variance filter

F1 = F2 =

(sets to zero in sky cut)

Make filtered maps

F1 F2 Quadratic estimator

Simulate * many times to calculate (accounts for anisotropic noise/sky cut)

Approximated or from sims

Reconstructed (Planck noise, Wiener filtered)

(thanks Duncan!)

- Constrain curvature, dark energy, neutrino mass…

For lensing get generalization of Okamoto & Hu 2003 estimators for anisotropic noise/partial sky

Hanson, Challinor & Lewis 0911.0612

True (simulated)

Sky modulation?

Popular modulation model:

QML estimator for f:

Cold spot?

WMAP power reconstruction (V band, KQ85 mask, foreground cleaned; reconstruction smoothed to 10 degrees)

Following Eriksen et al, WMAP, etc..

Unexpected signals?..

+ peak

of QML dipole

Dipole amplitude as function of lmax

Only ~1% modulation allowed on small scales

Consistent with Hirata 2009 - Very small observed anisotropy in quasar distribution

Modulation power spectrum lmax=64

Primordial power spectrum anisotropy

Look for direction-dependence in primordial power spectrum:

Anisotropic covariance:

Simple case:

e.g. Ackerman et.al. astro-ph/0701357 Gumrukcuoglu et al 0707.4179

Reconstruct g(k)

QML estimator:

Many-sigma quadrupole primordial power anisotropy??

Direction close to ecliptic! Also varies with frequency and detector.

Check with analytic model of scan strategy

Beam shape multipoles Scan strategy

WMAP model Hirata et al astro-ph/0406004.

Could it be systematics? - beam asymmetries? uncorrected in WMAP maps

Monte Carlo with subtraction of mean field analytic model of beam asymmetries

can be explained as correlated noise

No detection..

Consistent with Pullen et al 2010

constraint from large-scale structure 1003.0673

Bispectrum non-Gaussianity

• Local ‘squeezed’ models: small scale power correlated with large-scale temperature

• Considering large-scale modes to be fixed, expect power anisotropy

Liguori et al 2007

e.g. Local primordial non-Gaussianity

Write general quadratic anisotropy estimator:

In harmonic space

Creminelli et al 2005, Babich 2005, Smith & Zaldarriaga 2006

Bispectrum estimators are basically the cross-correlation of an anisotropy estimator with the temperature

Lensed temperature depends on deflection angle:

Lensing Potential

Deflection angle on sky given in terms of lensing potential

CMB lensing bispectrum

LensPix sky simulation code: http://cosmologist.info/lenspix Lewis 2005, Hammimeche & Lewis 2008

For squeezed triangles, 𝑙1 ≪ 𝑙2, 𝑙3,

𝑇 𝐥1 𝑇 𝐥2 𝑇 𝐥𝟑 ∼ 𝑇 𝐥1 𝜓 𝐥𝟏 ∼ 𝐶𝑙1

𝜓𝑇

𝑇 (𝐥𝟏) ∼ 𝑇(𝐥𝟏) and 𝑇 𝐥2 𝑇 𝐥3 𝑇 ∝ 𝜓(𝐥1)

Bispectrum measures cross-correlation of quadratic estimator for 𝜓 with the large-scale temperature

Bispectrum as statistical anisotropy correlation

Lensing by fixed 𝜓 field introduced statistical anisotropy Construct QML estimator for 𝜓 (following Hu and Okomoto 2003)

𝑇 𝐥2 𝑇 𝐥𝟏 − 𝐥𝟐 𝑇 ∝ 𝜓(𝐥1)

Why is there a correlation between large-scale lenses and the temperature?

Overdensity: magnification correlated with positive Integrated Sachs-Wolfe (net blueshift)

Underdensity: demagnification correlated with negative Integrated Sachs-Wolfe (net redshift)

(small-scales: also SZ , Rees-Sciama..)

Accurate bispectrum calculation Assume Gaussian fields. Non-perturbative result:

Use 𝑇 𝒙 = 𝑇(𝒙 + 𝛁𝜓)

~ Lensed temperature power spectrum

Lensing bispectrum depends on changes in the small-scale lensed power

𝑓𝑁𝐿 = 10

- Using lensed power spectra important at 5-20% level: leading-order result (using unlensed spectra) not accurate enough

𝑙1 = 4

- Quite large signal. Expect ∼ 5𝜎 with Planck. Cosmic variance ∼ 7𝜎.

(𝐥𝟏 + 𝐥𝟐 + 𝐥𝟑 = 0)

- Lensing bispectrum depends on power difference: has phase shift compared to any adiabatic primordial bispectrum (and different scale dependence)

- Lensing bispectrum is strongly scale dependent (small ISW for larger 𝑙1)

- Lensing bispectrum depends on shape of squeezed triangle (𝑙1 ⋅ 𝑙2 factor)

If lensing is neglected get bias Δ𝑓𝑁𝐿 ∼ 9 on primordial local models with Planck (see e.g. Hanson et al 0905.4732, Mangilli 0906.2317)

Lensing Local 𝑓𝑁𝐿

Local 𝑓𝑁𝐿 CMB temperature lensing

𝑙1 𝑙1

𝑙2 𝑙2

𝑙3 𝑙3

𝑏𝑙1𝑙2𝑙3

Lensing bispectrum also squeezed triangles but quite distinctive

Temperature bispectrum correlation with local 𝑓𝑁𝐿 ∼ 30%: in null hypothesis can measure amplitude using optimized estimator and accurately subtract from 𝑓𝑁𝐿 estimator

CMB polarization

General full-sky bispectrum:

Is the polarization correlated? 𝐶𝑙𝐸𝜓

+ perms

Z~1000

Hu astro-ph/9706147

Yes! Significant large-scale correlation due to reionization

Lensing potential correlation power spectra

Cosmic variance: C𝑇𝜓: ∼ 7𝜎, 𝐶𝐸𝜓: ∼ 2.5𝜎

𝑙1 = 4 𝑙1 = 50

𝑓𝑁𝐿 = 30

Also parity odd bispectra, TEB etc. (compared to sims)

𝑙1 = 4 𝑙1 = 50

Signal to Noise Signal quite large, so cosmic variance important as well as noise

Signal to noise

Contributions to Fisher inverse variance

Lensing signal peaks around 𝑙1 ∼ 30 - trade-off between size of signal and number of modes

- Cosmic variance limits simply determined by cosmic variance detection limits on

𝐶𝑙𝑇𝜓

and 𝐶𝑙𝐸𝜓

Planck ∼ 5𝜎; Cosmic Variance ∼ 9𝜎

Conclusions • Can easily test for and reconstruct many forms of Gaussian statistical anisotropy

- Fast nearly-optimal Quadratic Maximum Likelihood estimators

- Strong detection of ‘primordial power anisotropy’ in WMAP – but actually explained by beam asymmetries

- Lensing signal expected and can reconstruct lensing potential (learn about cosmological parameters)

• CMB lensing bispectrum is significant

- Temperature bispectrum from ISW-𝜓 correlation

- Also E- 𝜓 correlation (∼ 2.5𝜎 cosmic variance limit)

- Distinctive phase and scale-dependence

Should be detected by Planck

- Potential confusion with local 𝑓𝑁𝐿 but contribution easily distinguished/subtracted

- Also SZ correlation on smaller scales, but frequency dependent; other terms includes Rees Sciama (𝑓𝑁𝐿~ 1)

• Public codes available:

𝐶𝑙𝐸𝜓

, 𝐶𝑙𝑇𝜓

, 𝐶𝑙𝜓𝜓

, Local 𝑓𝑁𝐿 and lensing bispectrum in CAMB update: http://camb.info

CMB statistical anisotropy and the lensing bispectrum · 2010. 12. 10. · For squeezed triangles,...

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