prof. k. sato’s group as of 1986 (6 years after proposing inflation)
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Me(70kg). Prof Suto. Suto’s students. Me(62kg). Prof Kodama (KEK cosmophysics group). Prof. K. Sato’s group as of 1986 (6 years after proposing inflation). (Part of) UTAP/RESCEU as of 2008. Sarujima (Monkey Island) in Tokyo Bay. Inflation based on the first-order phase transition. - PowerPoint PPT PresentationTRANSCRIPT
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Prof. K. Sato’s group as of 1986(6 years after proposing inflation)
Sarujima (Monkey Island) in Tokyo Bay
Me(70kg) Me(62kg)
(Part of) UTAP/RESCEU as of 2008
Prof Suto Suto’s students
Prof Kodama (KEK cosmophysics group)
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On this slot of the symposium, originally Virginia Trimble was supposed to give a talk on the history of the concept Multiverse with the title“APERIO KOSMOI: Multiple Universes from the Ancients to 1981”but she could not come here in the end, because she could not pass through the security check at Los Angels Airport……???
Inflation based on the first-order phase transitionK. Sato MNRAS 195(1981)467; PLB99(1981)66, A. Guth PRD23(1981)347
cf New inflation A. Linde PLB108(1982)389, Albrechet & Steinhardt PRL 48(1982)1220 R2 theory A. Starobinskiy PLB91(1980)99 Chaotic inflation A. Linde PLB129(1983)177
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1981
eternal inflation of Vilenkin and Linde
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天文月報1991年3月号
Astronomical Herald March, 1991 (by Astronomical Society of Japan)
Reporting that Professor Sato wonNishina Memorial Prize
The paper of the multiproduction of the Universeswas epoch-making in the sense that the conventional cosmology dealing with “the one and only Universe”
was replaced by the new cosmology pushing “our Universe among many possible universes.”
triggered a transition of the vision of the Universe
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1981
eternal inflation of Vilenkin and Linde
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In the current paradigm of Inflationary Cosmology, in which the seeds of large scale structures and the anisotropy of CMBare explained in terms of quantum fluctuations of scalar fields,
We are observing one realization of the ensemble from a single point.
We must deal with the quantum ensemble of the universes whether there are many universes or only one.
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Errors are dominated by the cosmic varianceup to ℓ=407.
5-year WMAP data. TT angular power spectrum
Theoretical curveof the best-fitΛCDM model witha power-law initialspectrum
Even the binned data have somedeviations from thepower-law model.
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From the viewpoint of observational cosmology, the spectral shape of primordial curvature perturbation should be determined purely from observational data without any theoretical prejudice.
CosmicInversion
( )C P k
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Shown at Poster #C07 by Ryo Nagata
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As confirmed by WMAP observation, temperature fluctuation is Gaussian distributed.
with
Primordial Power spectrum
The probability distribution function (PDF) for each multipole is given by
( )P k
T
Ta Ylm lm
m l
l
l
, ,b g b g
0
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We insert the observed values
to the above PDF andregard it as a PDF for the power spectrum . ( )P k
N( : dispersion of observational noises)
The likelihood function is their products.
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Likelihood function for ( )P k
with
We assume the values of global cosmological parameters are fixed(to the WMAP best-fit values), and maximize the likelihood functionwith regard to the power spectrum .( )P k
χ2 distribution with degree 2 1
should be multipliedby the sky coveragefactor fsky .
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We solve
cf
We obtain a matrix equation.
-
kD kD kG kP obsC
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kD kG kP obsC N kD =k
kk k
#k dimensional square matrixbut we cannot invert it as it is, because the transfer function contained thereact as a smoothing function.
If we introduce some appropriate prior to the power spectrum, we canreconstruct it.Bayes theorem
Prior
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Prior for : “smoothness condition” cf (Tocchini-Valentini, Hoffman &Silk 05)( )P k
With this prior, the maximum likelihood equation
is modified to
The value of ε is chosen so that the reconstructed powerspectrum does not oscillate too much (in particular, to negative values) and that recalculated agree with observation well.
'sC
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130
2( ) ( ) sin
nA k k P k A k k B kd
T
start with a power spectrum with oscillatory modulation
C
calculate
( )A k
reconstruct
d : distance to LSS (13.4Gpc)
15T input
510 44 10
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130
2( ) ( ) sin
nA k k P k A k k B kd
T
C ( )A k
10T input
510 44 10
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130
2( ) ( ) sin
nA k k P k A k k B kd
T
C ( )A k
5T input
510 44 10
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Resolution depends on ε.Locations of peaks/dips are reproduced quite accurately.Always returns equal or smaller amplitudes = smoothed spectrum.Gives a conservative bound on any deviation from the power lawIf we find some deviation, actual power spectrum should have even larger deviation.
input510
44 10
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13.4Gpcd
We fix cosmological parameters to the best fit values ofthe power-law ΛCDM model based on WMAP5.
distance to the last scattering surface
We make 50000 samples of based on observed mean valuesand scatters around them based on the proper likelihood functionof WMAP and perform inversion for each sample.
C
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13.4Gpcd
kd
3 1 2 12.1 10 Mpc 2.7 10 Mpck
125kd peak & dips around
3( ) ( )A k k P k
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fits the observational data with binning well. 4
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k k k k( ) ( ) ( , )*t t P k t 3b gTheoretically, different k modes are uncorrelated.
Observationally reconstructed spectrum is correlated with nearbyk-modes.
limited by the transfer function
2( )X k
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Calculate the covariance matrix from N =50000 samples of the reconstructed power spectra.
Diagonalize the covariance matrix to constitute mutually independent band powers. The number of band powers is chosen so that their widths do not overlap with each other.
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Result of band power decompositionResult of band power decomposition
3.3σ deviation from power law
4 14 10 Mpc
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3 ( )k P k
40
Deviation around kd ≈ℓ≈40can be seen even in the
binned C ℓ but those at
125 can not be seen there.
(Nagata & JY 08)
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3 ( )k P k
a 3.3σdeviation
Statistical distribution accordingto WMAP likelihood function.
Statistical analysis of 50000 samples generated according toWMAP’s likelihood function shows that the probability to finda deviation above 3.3σ is 10-3. This is small.
But we have observed one such an event out of 40 band powers.10-3×40=0.04. This is large. I would be happy to live in a Universe which is realized in a “standard” theory with the probability of 4%.
@ 125kd
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3 ( )k P k
If we try to interpret the deviationfrom the band-power analysis only,we may well conclude that it is just a realization of a rare event amongmany random realizations of quantumensemble.
best-fit power lawBut if we look at the original unbinned angular power spectrumwe find some nontrivial oscillatorystructures that may have originatedin features in the primordial powerspectrum.
NB Correlation between different multipoles is less than 1%.
reconstructedpower spectrum
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30 400kd 35 405kd
In fact, if we change the wavenumber domain of decomposition slightly, we obtain a dip rather than an excess even for the band power analysis.
3.3peak
3dip
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Assume various shapes of modified power spectrumwith three additional parameters in addition to the standardpower-law.
Perform Markov-Chain Monte Carlo analysis with CosmoMCwith these three additional parameters in addition to the standard6 parameter ΛCDM model.
( )P k
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Transfer function shows that depends on with .
2( )
2 1
X k
C ( )P k kd
If we add some extra power on at , it would modifyall ’s with .C
125kd
( )P k125kd
kd
3 ( )k P k
Simply adding an extra power around does notmuch improve the likelihood, because it modifies the successful fit of power-law model at smaller ’s.
125kd
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Consider power spectra which change ’s only locally.C
kd
3( ) ( )A k k P k
v^ type
W type
S type
Height, location, & width of the peakare 3 additional parameters.
kd
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improves as much as 21 by introducing 3 additional parameters.2eff
If χ2 improves by 2 or more, it is worth introducing a new parameter, according to Akaike’s information criteria (AIC).
(Ichiki, Nagata, JY, 08)
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(based on 3 year WMAP data)
Running spectral index improves by 4. AIC OKRunning + tensor improve by 4. AIC marginal
2eff
2eff
(Our analysis of 5 year WMAP data shows that Running improves only by 1.8. AIC No )
2eff
(Spergel et al 07)
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Comparison with other non power-law, non standard models(based on 3 year WMAP data)
Binned power spectrum does not improve sufficiently,if binning is done with no reference to the observational data.
2eff
It is very difficult to improve the fit. Inverse analysis is very important!
125
720Mpc
kd
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Unlike our reconstruction methods, MCMC calculations usenot only TT data but also TE data.
2eff due to improvement of TT fit =
due to improvement of TE fit =2eff
It is intriguing that our modified spectra improve TE fit significantly even if we only used TT data in the beginning.
12.58.5
TT(temp-temp) data and model TE(temp-Epol) data and model
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92.32 10A
Probability to find is only . 101.43 10B 52.2 10
1010B
Posterior distribution in MCMC calculation with
Rel
ativ
e fr
eque
ncy
(for ) * 100 150k d (tentative)
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The tentative probability that the primordial power spectrum has a nonvanishing modulation (at some wave number) is estimated to be ~ 99.98%.P k t ti i( , ) | ( )| k
2
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The presence of such a fine structure changes the estimate ofother cosmological parameters at an appreciable level.
modulated spectra
Maximum of the shift from the power law
ExpectedErrors byPLANCK
observed errors with WMAP5
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If we wish to evaluate the values of the cosmological parameters ofour current Universe with high accuracy, we should take possiblenontrivial, non-power-law features into account.
Whether they have any physical origin or are just a particular realization of random fluctuations, they are properties of our own Universe.
We should investigate their characteristic features (and impacton other parameters), even if this may not be an physics issue.
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To find something interesting Abstract information by Fourierdecomposition.
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With the next generation (or perhaps next-to-next generation)of higher precision observations,Cosmology will inevitably turn to Astronomy from Physics.This could be regarded as a triumph of physics.
APERIO KOSMOS
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A brief history of Katsuhiko SatoA brief history of Katsuhiko Sato
born on August 30, 1945 PhD from Kyoto University (supervisor: Chushiro
Hayashi)Kyoto University, NORDITA(1979-1980), University of Tokyo (1982-)Dean of Faculty of Science (2001-2003), Director of RESCEU (1999-2001, 2003-2007) President of IAU commission 47 (cosmology; 1988-
1991), president of Phys. Soc. Japan (1997-1998, 2005-2006)
the 5th Inoue Foundation Prize (1989) the 36th Nishina memorial prize (1990)紫綬褒章 Medal with purple ribbon (2002)
born on August 30, 1945 PhD from Kyoto University (supervisor: Chushiro
Hayashi)Kyoto University, NORDITA(1979-1980), University of Tokyo (1982-)Dean of Faculty of Science (2001-2003), Director of RESCEU (1999-2001, 2003-2007) President of IAU commission 47 (cosmology; 1988-
1991), president of Phys. Soc. Japan (1997-1998, 2005-2006)
the 5th Inoue Foundation Prize (1989) the 36th Nishina memorial prize (1990)紫綬褒章 Medal with purple ribbon (2002)
Tokyo
Kagawa
Kochi
Kyoto
Gunma
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A brief history of Katsuhiko SatoA brief history of Katsuhiko Sato
born on August 30, 1945 PhD from Kyoto University (supervisor: Chushiro
Hayashi)Kyoto University, NORDITA(1979-1980), University of Tokyo (1982-)Dean of Faculty of Science (2001-2003),Director of RESCEU (1999-2001, 2003-2007) President of IAU commission 47 (cosmology; 1988-
1991), President of Phys. Soc. Japan (1997-1998, 2005-2006)
the 5th Inoue Foundation Prize (1989) the 36th Nishina memorial prize (1990)紫綬褒章 Medal with purple ribbon (2002)
born on August 30, 1945 PhD from Kyoto University (supervisor: Chushiro
Hayashi)Kyoto University, NORDITA(1979-1980), University of Tokyo (1982-)Dean of Faculty of Science (2001-2003),Director of RESCEU (1999-2001, 2003-2007) President of IAU commission 47 (cosmology; 1988-
1991), President of Phys. Soc. Japan (1997-1998, 2005-2006)
the 5th Inoue Foundation Prize (1989) the 36th Nishina memorial prize (1990)紫綬褒章 Medal with purple ribbon (2002)
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List of the graduate students supervised by Professor Sato
32 PhDs 4 PhD candidates 12 Masters
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