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Type Ia Supernovae on a glass:The bread and butter of peculiar velocities Lunch meeting Aarhus, March 2007
Troels Haugbøllehaugboel@phys.au.dk
Institute for Physics & Astronomy, Århus University
Collaborators:Steen Hannestad, Bjarne Thomsen
Goals of our project
● Predict how well we can probe the local velocity field, with upcoming supernovae surveys
● Design the optimal observational strategy to maximize science output
● Understand how the angular power spectrum of the peculiar velocity field can be used as a tool for constraining cosmology
Velocity Fields
● Velocity trace mass:● The peculiar velocity field is sourced by the gravitational
potential: It is directly dependent on the dark matter dist No bias!
● Further away than ~100 Mpc h-1 cosmic variance is small, and we can constrain cosmological models!The velocity field 30 Mpc away The density field 30 Mpc away
-560 960 km/s
velocity contra density
● To measure the density we have to ● count standard objects● take care not to miss any!
● Density is derived from number counts. ● Then put in the conversion from
luminosity to mass, completeness, bias to dark matter etc
● The velocity field can be ● measured directly and sparsely ● Good, since there are few SnIa’s
● At large distances the Hubble Flow dominate
How to measure vr
● Requisites:The redshift of the host galaxyThe distance or the apparent and absolute magnitudes
● Traditionally used methods to obtain the distance include● The Tully-Fisher relation● Surface brightness fluctuations● Fundamental plane● Reconstruction from the density field of redshift surveys
● They all have an intrinsic scatter of at least m=0.3-0.4
How to measure vr
● Requisites:The redshift of the host galaxyThe distance or the apparent and absolute magnitudes
● Traditionally used methods to obtain the distance include● The Tully-Fisher relation● Surface brightness fluctuations● Fundamental plane● Reconstruction from the density field of redshift surveys
● They all have an intrinsic scatter of at least m=0.3-0.4
● With upcoming surveys Type Ia Supernovae will have an intrinsic scatter of m=0.08-0.1
Upcoming surveys● The change in apparent magnitude with redshift is used to
constrain the cosmology. Many surveys will be done the next couple of years.
(Hui & Greene a-ph/0512159)
QuickTime™ and aTIFF (Uncompressed) decompressor
are needed to see this picture.
Upcoming surveys● Unfortunately surveys have small FOV, and are designed for
high redshift SNe. In fact weak lensing/asteroid surveys are better for local supernovae. They scan the sky continuously, and observe in many bands (typically 6)
Pan-Starrs Sky Mapper
4x1.4Gp
2007
256Mp
2008
Hawaii Australia
LSST3.2Gp
2013
Chile
Forecast● We know the local supernova rate
● This gives 60000 Type Ia SN per year inside a distance of 500 h-1 Mpc
Typically peculiar velocities are ~ 400 km s-1
● We want to look at the angular distribution as a function of distance. Binning in a reasonable manner we have
1100 SnIa at 60 h-1Mpc with error vr ~ 220 km s-1
7000 SnIa at 150 h-1Mpc with error vr ~ 550 km s-1
35000 SnIa at 350 h-1Mpc with error vr ~ 1300 km s-1
Forecast● We know the local supernova rate
● This gives 60000 Type Ia SN per year inside a distance of 500 h-1 Mpc
● There are light curves, but we need precise redshifts● Low redshift Type Ia Supernovae are not a priority
● We need to do it ourselves● It is not realistic to measure 60000 redshifts per year.
How to make a supernova survey
Make Nbody sim
Find density and velocity on a spherical shell
Populate with Supernovae
Calculate Power spectrum
...but there is more to it
● With a limited amount of SNe, we can only measure a limited part of the powerspectrum
● Algorithm:● Given a set of Supernovae. Calculate powerspectrum
...but there is more to it
● With a limited amount of SNe, we can only measure a limited part of the powerspectrum
● Algorithm:● Given a set of Supernovae. Calculate powerspectrum● Make N mock catalogues with same errors
...but there is more to it
● With a limited amount of SNe, we can only measure a limited part of the powerspectrum
● Algorithm:● Given a set of Supernovae. Calculate powerspectrum● Make N mock catalogues with same errors● Compare the mock powerspectra to the underlying
powerspectrum● This gives the error term
...but there is more to it
● With a limited amount of SNe, we can only measure a limited part of the powerspectrum
● Algorithm:● Given a set of Supernovae. Calculate powerspectrum● Make N mock catalogues with same errors● Compare the mock powerspectra to the underlying
powerspectrum● This gives the error term
● Subtract the error term from the observed powerspectrum
QuickTime™ and aTIFF (Uncompressed) decompressor
are needed to see this picture.
Supernovae on a glass
● We know the local supernova rate
● This gives 60000 Type Ia SN per year inside a distance of 500 h-1 Mpc
● There are light curves, but we need precise redshifts● Low redshift Type Ia Supernovae are not a priority
● We need to do it ourselves● It is not realistic to measure 60000 redshifts per year.
QuickTime™ and aTIFF (Uncompressed) decompressor
are needed to see this picture.
QuickTime™ and aTIFF (Uncompressed) decompressor
are needed to see this picture.
Goals of our project
● Predict how well we can probe the local velocity field, with upcoming supernovae surveys
● Design the optimal observational strategy to maximize science output
● Understand how the angular power spectrum of the peculiar velocity field can be used as tool for constraining cosmology
Connecting the matter and velocity powerspectrum
● Velocity trace mass:● The angular velocity powerspectrum is related to
the matter powerspectrum:
● Which can be simplified to:
Connecting the matter and velocity powerspectrum
QuickTime™ and aTIFF (Uncompressed) decompressor
are needed to see this picture.
QuickTime™ and aTIFF (Uncompressed) decompressor
are needed to see this picture.
● We can find the average amplitude between
l=5-20● It is free of cosmic variance
Consequences for cosmology● The overall amplitude depends on
This combination break
degeneracies,and8 can be constrained
● The form of the velocity powerspectrum is directly related to the shape parameter
● The amplitude and shape at l=5-20 is not affected much by cosmic variance
● Success depends on proper observational strategy - can I have a glass, please?
Other factors apply to the lumi-nosity distance at high redshift
(Sugiura et al ‘99,Hui & Greene a-ph/0512159, Bonvin et al a-ph/0511183)
Light travels along geodesics, and is influenced by:
● The peculiar motion of the source and the observer, giving rise to a redshift.
● Gravitational lensing. It (de)magnifies the light rays and depends on the fluctuations in the gravitational potential● Gravitational redshift
● An integrated effect from line-of-sight change in the potential (Sachs-Wolfe effect)
Other factors apply to the lumi-nosity distance at high redshift
(Sugiura et al ‘99,Hui & Greene a-ph/0512159, Bonvin et al a-ph/0511183)
Light travels along geodesics, and is influenced by:
● The peculiar motion of the source and the observer, giving rise to a redshift.
● Gravitational lensing. It (de)magnifies the light rays and depends on the fluctuations in the gravitational potential● Gravitational redshift
● An integrated effect from line-of-sight change in the potential (Sachs-Wolfe effect)
Important at low redshift
Important at high redshift
Are we living in a Hubble Bubble?(Zehavi et al a-ph/9802252)
● Used 44 SnIa● H= vr / dL
● Model suggest we are in an underdense region with radius of 70 Mpc h-1
Can we trust the local Hubble parameter?
(Shi a-ph/9707101,Shi MNRAS, 98 )
● Used 20 SnIa (Upper plot) and 36 clusters with T-F relation
● Make CDM models that mimick the local density fields
● Run different cosmological scenarioes
● Compare! It is hard to see the difference, with current data.
● There is a 2% error on H0 out to about 250 Mpc h-1
How big is the dipole?(Bonvin et al a-ph/0603240)
● Use the same 44 SnIa● As a test, given H0, measure the
CMB dipole● Gives 405±192 km/s
How big is the dipole?(Bonvin et al a-ph/0603240)
● Use the same 44 SnIa● As a test, given H0, measure the
CMB dipole● In the future: Given the CMB dipole
amplitude |v0|, measure H(z)● 100’s of SnIa’s needed for 30% error
The lowest multipoles and the local universe
● The lowest multipoles of the angular powerspectrum are easy to understand
● The monopole gives the contraction/expansion
● The dipole measures average flow
● The quadrupole represents the first shear mode
The peculiar velocity at higher redshifts and the cosmic web
Timeline in movie
To give a feeling for the cosmic large scale structure I will show you two movies, where we slowly zoom out and see structure further and further away
Distance to the observer
The peculiar velocity at higher redshifts and the cosmic web
QuickTime™ and aBMP decompressor
are needed to see this picture.
The angular powerspectrum
Size of voids
Size of clusters
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