Abstract / Description of output
We have derived estimators for the linear growth rate of density
fluctuations using the cross-correlation function (CCF) of voids and
haloes in redshift space. In linear theory, this CCF contains only
monopole and quadrupole terms. At scales greater than the void radius,
linear theory is a good match to voids traced out by haloes; small-scale
random velocities are unimportant at these radii, only tending to cause
small and often negligible elongation of the CCF near its origin. By
extracting the monopole and quadrupole from the CCF, we measure the
linear growth rate without prior knowledge of the void profile or
velocity dispersion. We recover the linear growth parameter β to 9
per cent precision from an effective volume of 3(
h-1Gpc)3 using voids with radius >25
h-1Mpc. Smaller voids are predominantly sub-voids, which may
be more sensitive to the random velocity dispersion; they introduce
noise and do not help to improve measurements. Adding velocity
dispersion as a free parameter allows us to use information at radii as
small as half of the void radius. The precision on β is reduced to
5 per cent. Voids show diverse shapes in redshift space, and can appear
either elongated or flattened along the line of sight. This can be
explained by the competing amplitudes of the local density contrast,
plus the radial velocity profile and its gradient. The distortion
pattern is therefore determined solely by the void profile and is
different for void-in-cloud and void-in-void. This diversity of
redshift-space void morphology complicates measurements of the
Alcock-Paczynski effect using voids.
Original language | English |
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Pages (from-to) | 2465-2477 |
Journal | Monthly Notices of the Royal Astronomical Society |
Volume | 462 |
Issue number | 3 |
DOIs | |
Publication status | Published - 28 Jul 2016 |
Keywords / Materials (for Non-textual outputs)
- methods: analytical
- methods: numerical
- methods: statistical
- large-scale structure of Universe
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Dive into the research topics of 'Redshift-space distortions around voids'. Together they form a unique fingerprint.Profiles
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Yan-Chuan Cai
- School of Physics and Astronomy - Reader
Person: Academic: Research Active (Research Assistant)
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Andy Taylor
- School of Physics and Astronomy - Personal Chair in Astrophysics
Person: Academic: Research Active