Is there a preferred direction in the Universe P. Jain, IIT Kanpur There appear to be several indications of the existence of a preferred direction in the Universe (or a breakdown of isotropy) Optical polarizations from distant AGNs Radio polarizations from distant AGNs Low order multipoles of CMBR
On distance scales of less than 100 Mpc the Universe is not homogeneous and isotropic The Virgo cluster sits at the center of this disc like structure Most galaxies in our vicinity lie in a plane (the supergalactic plane) which is approximately perpendicular to the galactic plane. On larger distance scales the universe appears isotropic
CFA Survey 1986
WMAP released very high resolution data in march 2003 Total number of pixels = 512 x 512 x 12 The data is available at 5 frequencies There is considerable contamination from foreground emissions which complicate the interpretation of dataCMBR What does CMBR imply about the isotropy of the universe?
CMBR Probe WMAP
K band 23 GHz Ka band 33 GHz Q band 41 GHz V band 61 GHzW band 94 GHz WMAP multi-frequency maps
T Temperature Fluctuations about the mean Two Point Correlation Function Statistical isotropy implies
If we assume that T (and a lm ) are Gaussian random variables (with 0 mean) then all the statistical information is contained in the two point correlation function or
TT Cross Power Spectrum
The power is low at small l (quadrupole l=2) The probability for such a low quadrupole to occur by a random fluctuation is 5% Oliveira-Costa et al 2003 The Octopole is not small but very planar Surprisingly the Octopole and Quadrupole appear to be aligned with one another with the chance probability =1/62
Quadrupole Octopole Cleaned Map Oliveira-Costa et al 2003 All the hot and cold spots of the Quadrupole and Octopole lie in a plane, inclined at approx 30 o to galactic plane
Extraction of Preferred Axis Imagine T as a wave function Maximize the angular momentum dispersion Oliveira-Costa et al 2003
Extraction of Preferred Axis k = 1 …3, m = -l … l Preferred frame e k is obtained by Singular Value Decomposition e represent 3 orthogonal axes in space The preferred axes is the one with largest eigenvalue Ralston, Jain 2003 Alternatively Define
The preferred axis for both Quadrupole and Octopole points roughly in the direction (l,b) (-110 o,60 o ) in Virgo Constellation
Hence WMAP data suggests the existence of a preferred direction (pointing towards Virgo) We (Ralston and Jain, 2003) show that there is considerable more evidence for this preferred direction CMBR dipole Anisotropy in radio polarizations from distant AGNs Two point correlations in optical polarizations from AGNs Also point in this direction
CMBR Dipole The dipole is assumed to arise due to the local (peculiar) motion of the milky way, arising due to local in-homogeneities The observed dipole also points in the direction of Virgo
Physical Explanations Many explanations have been proposed for the anomalous behavior of the low order harmonics Non trivial topology (Luminet, Weeks, Riazuelo, Leboucq and Uzan, 2003) Anisotropic Universe (Berera, Buniy and Kephart, 2003) Sunyaev Zeldovich effect due to local supercluster (Abramo and Sodre, 2003)
Offset angle RM) RM : Faraday Rotation Measure = IPA (Polarization at source) Anisotropy in Radio Polarizations shows a Dipole ANISOTROPY Radio Polarizations from distant AGNs show a dipole anisotropy Birch 1982 Jain, Ralston, 1999 Jain, Sarala, 2003
Likelihood Analysis The Anisotropy is significant at 1% in full (332 sources) data set and 0.06% after making a cut in RM (265 sources) RM - | > 6 rad/m = 6 rad/m = polarization offset angle
Distribution of RM The cut eliminates the data near the central peak
The radio dipole axis also points towards Virgo Jain and Ralston, 1999
Anisotropy in Extragalactic Radio Polarizations beta = polarization offset angle Using the cut |RM - | > 6 rad/m 2
Anisotropy in Extragalactic Radio Polarizations Using the cut |RM - | > 6 rad/m 2 Galactic Coordinates
Equatorial Coordinates Anisotropy in Extragalactic Radio Polarizations A generalized (RM dependent) statistic indicates that the entire data set shows dipole anisotropy
Possible Explanation An anisotropically distributed background pseudoscalar field of sufficiently large strength can explain the observations To account for the RM dependence Rotation in polarization =g ( change in the pseudoscalar field along the path Pseudoscalar field at source g < GeV -1
Hutsemékers Effect Optical Polarizations of QSOs appear to be locally aligned with one another. (Hutsemékers, 1998) A very strong alignment is seen in the direction of Virgo cluster 1<z<2.3
Hutsemékers Effect Equatorial Coordinates 1<z<2.3
Statistical Analysis A measure of alignment is obtained by comparing polarization angles in a local neighborhood The polarizations at different angular positions are compared by making a parallel transport along the great circle joining the two points
Maximizing d i ( ) with respect to gives a measure of alignment D i and the mean angle Statistic k, k=1…n v are the polarizations of the n v nearest neighbours of the source i k i = contribution due to parallel transport Statistic Jain, Narain and Sarala, 2003
We find a strong signal of redshift dependent alignment in a data sample of 213 quasars Alignment Results Low polarization sample (p < 2%) High redshift sample (z > 1) The strongest signal is seen in
Significance Level
Large redshifts (z > 1) show alignment over the entire sky
Alignment Statistic (z > 1)
Alignment Results Strongest correlation is seen at low polarizations ( p < 2%) at distance scales of order Gpc Large redshifts z > 1 show alignment over the entire sky Jain, Narain and Sarala, 2003
Possible Explanation Optical Alignment can also be explained by a pseudoscalar field. As the EM wave passes through large scale magnetic field, photons (polarized parallel to transverse magnetic field) decay into pseudoscalars The wave gets polarized perpendicular to the transverse magnetic field But we require magnetic field on cosmologically large distance scales Jain, Panda and Sarala, 2002
Preferred Axis Two point correlation Define the correlation tensor Define where is the matrix of sky locations S is a unit matrix for an isotropic uncorrelated sample
Preferred Axis Optical axis is the eigenvector of S with maximum eigenvalue
Alignment Statistic Preferred axis points towards (or opposite) to Virgo Degree of Polarization < 2%
dipolequadoctoradiooptical dipole quad octo radio0.008 Prob. for pairwise coincidences Ralston and Jain, 2003
Concluding Remarks There appears to be considerable evidence that there is a preferred direction in the Universe pointing towards Virgo However the CMBR observations may also be explained in terms of some local distortion of microwave photons due to supercluster. The physical mechanism responsible for this is not known so far. However it is not possible to attribute optical alignment to a local effect Future observations will hopefully clarify the situation Radio anisotropy may also arise due to some local unknown effect
Anisotropy in Extragalactic Radio Polarizations sin(2 ) < 0 + sin(2 ) > 0 Using the cut |RM - | > 6 rad/m 2
Significance Level of Radio Anisotropy
Radiation propagating over cosmological distances also probes isotropy of the Universe CMBR Radiation from distant AGNs
The 3-dim space appears the same in all directions and at all locations One way to test for isotropy and homogeneity is by observing the density of matter (galaxies) in different directions and positions Angular correlation function or 3-D correlation function On Large scale it is assumed that Universe is Isotropic and Homogeneous
APM Survey 100 degrees by 50 degrees around the South Galactic Pole Intensities scaled to the number of galaxies blue, green and red for bright, medium and faint galaxies
The APM survey has about 5 million galaxies It gives an accurate measure of the angular two point correlation function to about 10 degrees The results agree reasonably well with the CDM model with Dodelson (2003) Maddox et al (1990)