Modeling and measuring the anisotropic halo 3-point correlation function: a coordinated study

Ongoing spectroscopic galaxy surveys like DESI (arXiv:1611.00037, arXiv:1611.00036) and Euclid (arXiv:2405.13491) will cover unprecedented volumes with a number of objects large enough to effectively probe clustering anisotropies through higher-order statistics. In this work, we present an original and efficient implementation of both a model for the multipole moments of the anisotropic 3-point correlation function (3PCF) and for their estimator. To assess the adequacy of our model, we have predicted the anisotropic 3PCF for a set of dark matter halos at redshift $z = 1$ and compared our prediction with the 3PCF measurement obtained by applying our estimator to a suite of 298 N-body + 3000 approximate mock halo catalogs at the same redshift. The use of the anisotropic component of the 3PCF effectively breaks the degeneracy between the growth rate $f$ and the linear bias $b_1$, allowing us to obtain unbiased estimates for both parameters from a Euclid-like survey. A joint, full anisotropic, 2 and 3-point correlation analysis would also allow us to measure the clustering amplitude $\sigma_8$ along with $f$ and $b_1$ with a precision of approximately 17%, and to effectively constrain all galaxy biasing parameters of the model. However, these results largely exploit information from the isotropic part of the 3PCF signal. The addition of the anisotropic multipoles tightens parameter estimates by just 5% at most. We argue that this modest improvement likely reflects the use of a simplified cosmological model with relatively few free parameters. The 3PCF anisotropic multipoles will prove useful in reducing the impact of projection effects that affect high-dimensional cosmological analyses. To support this conjecture, we provide an example in which an additional source of anisotropy, the Alcock-Paczynski effect, is added to the system.