Abstract
Studies of intrinsic alignment effects mostly focus on the correlations
between the shapes of galaxies with each other or with the underlying
density field of the large scale structure of the Universe. Lately, the
correlation between the shapes of galaxies and the large-scale velocity
field has been proposed as an additional probe of the large scale
structure. We use a Fisher forecast to make a prediction for the
detectability of this velocity-shape correlation with a combination of
redshifts and shapes from the 4 MOST +LSST surveys, and radial velocity
reconstruction from the Simons Observatory. The signal-to-noise ratio
for the velocity-shape (dipole) correlation is 23, relative to 44 for
the galaxy density-shape (monopole) correlation and for a maximum wave
number of 0.2 Mpc-1 . Increasing the signal-to-noise ratio
for higher values of the maximum wave numbers (respectively, 56 and 69,
for a maximum wave number of 1 Mpc-1 ) indicate potential
gains in the nonlinear regime. Encouraged by these predictions, we
discuss two possible applications for the velocity-shape correlation.
Measuring the velocity-shape correlation could improve the mitigation of
selection effects induced by intrinsic alignments on galaxy clustering.
We also find that velocity-shape measurements could potentially aid in
determining the scale dependence of intrinsic alignments when multiple
shape measurements of the same galaxies are provided.
Original language | English |
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Article number | 123507 |
Journal | Physical Review D |
Volume | 102 |
Issue number | 12 |
DOIs | |
Publication status | Published - 1 Dec 2020 |