The wiggleZ dark energy survey: Measuring the cosmic growth rate with the two-point galaxy correlation function

Carlos Contreras; Chris Blake; Gregory B. Poole; Felipe Marin; Sarah Brough; Matthew Colless; Warrick Couch; Scott Croom; Darren Croton; Tamara M. Davis; Michael J. Drinkwater; Karl Forster; David Gilbank; Mike Gladders; Karl Glazebrook; Ben Jelliffe; Russell J. Jurek; I. Hui Li; Barry Madore; D. Christopher Martin; Kevin Pimbblet; Michael Pracy; Rob Sharp; Emily Wisnioski; David Woods; Ted K. Wyder; H. K.C. Yee

doi:10.1093/mnras/sts608

The wiggleZ dark energy survey: Measuring the cosmic growth rate with the two-point galaxy correlation function

Carlos Contreras^*, Chris Blake, Gregory B. Poole, Felipe Marin, Sarah Brough, Matthew Colless, Warrick Couch, Scott Croom, Darren Croton, Tamara M. Davis, Michael J. Drinkwater, Karl Forster, David Gilbank, Mike Gladders, Karl Glazebrook, Ben Jelliffe, Russell J. Jurek, I. Hui Li, Barry Madore, D. Christopher MartinKevin Pimbblet, Michael Pracy, Rob Sharp, Emily Wisnioski, David Woods, Ted K. Wyder, H. K.C. Yee

^*Corresponding author for this work

Research output: Contribution to journal › Article › peer-review

38 Citations (Scopus)

Abstract

The growth history of large-scale structure in the Universe is a powerful probe of the cosmological model, including the nature of dark energy. We study the growth rate of cosmic structure to redshift z = 0.9 using more than 162 000 galaxy redshifts from the WiggleZ Dark Energy Survey. We divide the data into four redshift slices with effective redshifts z = [0.2, 0.4, 0.6, 0.76] and in each of the samples measure and model the two-point galaxy correlation function in parallel and transverse directions to the line of sight. After simultaneously fitting for the galaxy bias factor we recover values for the cosmic growth rate which are consistent with our assumed Λcold dark matter (ΛCDM) input cosmological model, with an accuracy of around 20 per cent in each redshift slice. We investigate the sensitivity of our results to the details of the assumed model and the range of physical scales fitted, making close comparison with a set of N-body simulations for calibration. Our measurements are consistent with an independent power-spectrum analysis of a similar data set, demonstrating that the results are not driven by systematic errors. We determine the pairwise velocity dispersion of the sample in a non-parametric manner, showing that it systematically increases with decreasing redshift, and investigate the Alcock-Paczynski effects of changing the assumed fiducial model on the results. Our techniques should prove useful for current and future galaxy surveys mapping the growth rate of structure using the two-dimensional correlation function.

Original language	English
Pages (from-to)	924-933
Number of pages	10
Journal	Monthly Notices of the Royal Astronomical Society
Volume	430
Issue number	2
DOIs	https://doi.org/10.1093/mnras/sts608
Publication status	Published - 1 Apr 2013

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Contreras, C., Blake, C., Poole, G. B., Marin, F., Brough, S., Colless, M., Couch, W., Croom, S., Croton, D., Davis, T. M., Drinkwater, M. J., Forster, K., Gilbank, D., Gladders, M., Glazebrook, K., Jelliffe, B., Jurek, R. J., Li, I. H., Madore, B., ... Yee, H. K. C. (2013). The wiggleZ dark energy survey: Measuring the cosmic growth rate with the two-point galaxy correlation function. Monthly Notices of the Royal Astronomical Society, 430(2), 924-933. https://doi.org/10.1093/mnras/sts608

@article{2f578fe87998442182c4eb1dc2b5675d,

title = "The wiggleZ dark energy survey: Measuring the cosmic growth rate with the two-point galaxy correlation function",

abstract = "The growth history of large-scale structure in the Universe is a powerful probe of the cosmological model, including the nature of dark energy. We study the growth rate of cosmic structure to redshift z = 0.9 using more than 162 000 galaxy redshifts from the WiggleZ Dark Energy Survey. We divide the data into four redshift slices with effective redshifts z = [0.2, 0.4, 0.6, 0.76] and in each of the samples measure and model the two-point galaxy correlation function in parallel and transverse directions to the line of sight. After simultaneously fitting for the galaxy bias factor we recover values for the cosmic growth rate which are consistent with our assumed Λcold dark matter (ΛCDM) input cosmological model, with an accuracy of around 20 per cent in each redshift slice. We investigate the sensitivity of our results to the details of the assumed model and the range of physical scales fitted, making close comparison with a set of N-body simulations for calibration. Our measurements are consistent with an independent power-spectrum analysis of a similar data set, demonstrating that the results are not driven by systematic errors. We determine the pairwise velocity dispersion of the sample in a non-parametric manner, showing that it systematically increases with decreasing redshift, and investigate the Alcock-Paczynski effects of changing the assumed fiducial model on the results. Our techniques should prove useful for current and future galaxy surveys mapping the growth rate of structure using the two-dimensional correlation function.",

keywords = "Cosmological parameters, Large-scale structure of universe, Surveys",

author = "Carlos Contreras and Chris Blake and Poole, {Gregory B.} and Felipe Marin and Sarah Brough and Matthew Colless and Warrick Couch and Scott Croom and Darren Croton and Davis, {Tamara M.} and Drinkwater, {Michael J.} and Karl Forster and David Gilbank and Mike Gladders and Karl Glazebrook and Ben Jelliffe and Jurek, {Russell J.} and Li, {I. Hui} and Barry Madore and {Christopher Martin}, D. and Kevin Pimbblet and Michael Pracy and Rob Sharp and Emily Wisnioski and David Woods and Wyder, {Ted K.} and Yee, {H. K.C.}",

year = "2013",

month = apr,

day = "1",

doi = "10.1093/mnras/sts608",

language = "English",

volume = "430",

pages = "924--933",

journal = "Monthly Notices of the Royal Astronomical Society",

issn = "0035-8711",

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Contreras, C, Blake, C, Poole, GB, Marin, F, Brough, S, Colless, M, Couch, W, Croom, S, Croton, D, Davis, TM, Drinkwater, MJ, Forster, K, Gilbank, D, Gladders, M, Glazebrook, K, Jelliffe, B, Jurek, RJ, Li, IH, Madore, B, Christopher Martin, D, Pimbblet, K, Pracy, M, Sharp, R , Wisnioski, E, Woods, D, Wyder, TK & Yee, HKC 2013, 'The wiggleZ dark energy survey: Measuring the cosmic growth rate with the two-point galaxy correlation function', Monthly Notices of the Royal Astronomical Society, vol. 430, no. 2, pp. 924-933. https://doi.org/10.1093/mnras/sts608

TY - JOUR

T1 - The wiggleZ dark energy survey

T2 - Measuring the cosmic growth rate with the two-point galaxy correlation function

AU - Contreras, Carlos

AU - Blake, Chris

AU - Poole, Gregory B.

AU - Marin, Felipe

AU - Brough, Sarah

AU - Colless, Matthew

AU - Couch, Warrick

AU - Croom, Scott

AU - Croton, Darren

AU - Davis, Tamara M.

AU - Drinkwater, Michael J.

AU - Forster, Karl

AU - Gilbank, David

AU - Gladders, Mike

AU - Glazebrook, Karl

AU - Jelliffe, Ben

AU - Jurek, Russell J.

AU - Li, I. Hui

AU - Madore, Barry

AU - Christopher Martin, D.

AU - Pimbblet, Kevin

AU - Pracy, Michael

AU - Sharp, Rob

AU - Wisnioski, Emily

AU - Woods, David

AU - Wyder, Ted K.

AU - Yee, H. K.C.

PY - 2013/4/1

Y1 - 2013/4/1

N2 - The growth history of large-scale structure in the Universe is a powerful probe of the cosmological model, including the nature of dark energy. We study the growth rate of cosmic structure to redshift z = 0.9 using more than 162 000 galaxy redshifts from the WiggleZ Dark Energy Survey. We divide the data into four redshift slices with effective redshifts z = [0.2, 0.4, 0.6, 0.76] and in each of the samples measure and model the two-point galaxy correlation function in parallel and transverse directions to the line of sight. After simultaneously fitting for the galaxy bias factor we recover values for the cosmic growth rate which are consistent with our assumed Λcold dark matter (ΛCDM) input cosmological model, with an accuracy of around 20 per cent in each redshift slice. We investigate the sensitivity of our results to the details of the assumed model and the range of physical scales fitted, making close comparison with a set of N-body simulations for calibration. Our measurements are consistent with an independent power-spectrum analysis of a similar data set, demonstrating that the results are not driven by systematic errors. We determine the pairwise velocity dispersion of the sample in a non-parametric manner, showing that it systematically increases with decreasing redshift, and investigate the Alcock-Paczynski effects of changing the assumed fiducial model on the results. Our techniques should prove useful for current and future galaxy surveys mapping the growth rate of structure using the two-dimensional correlation function.

AB - The growth history of large-scale structure in the Universe is a powerful probe of the cosmological model, including the nature of dark energy. We study the growth rate of cosmic structure to redshift z = 0.9 using more than 162 000 galaxy redshifts from the WiggleZ Dark Energy Survey. We divide the data into four redshift slices with effective redshifts z = [0.2, 0.4, 0.6, 0.76] and in each of the samples measure and model the two-point galaxy correlation function in parallel and transverse directions to the line of sight. After simultaneously fitting for the galaxy bias factor we recover values for the cosmic growth rate which are consistent with our assumed Λcold dark matter (ΛCDM) input cosmological model, with an accuracy of around 20 per cent in each redshift slice. We investigate the sensitivity of our results to the details of the assumed model and the range of physical scales fitted, making close comparison with a set of N-body simulations for calibration. Our measurements are consistent with an independent power-spectrum analysis of a similar data set, demonstrating that the results are not driven by systematic errors. We determine the pairwise velocity dispersion of the sample in a non-parametric manner, showing that it systematically increases with decreasing redshift, and investigate the Alcock-Paczynski effects of changing the assumed fiducial model on the results. Our techniques should prove useful for current and future galaxy surveys mapping the growth rate of structure using the two-dimensional correlation function.

KW - Cosmological parameters

KW - Large-scale structure of universe

KW - Surveys

UR - http://www.scopus.com/inward/record.url?scp=84876695862&partnerID=8YFLogxK

U2 - 10.1093/mnras/sts608

DO - 10.1093/mnras/sts608

M3 - Article

SN - 0035-8711

VL - 430

SP - 924

EP - 933

JO - Monthly Notices of the Royal Astronomical Society

JF - Monthly Notices of the Royal Astronomical Society

IS - 2

ER -

The wiggleZ dark energy survey: Measuring the cosmic growth rate with the two-point galaxy correlation function

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