TY - JOUR
T1 - Very massive tracers and higher derivative biases
AU - Fujita, Tomohiro
AU - Mauerhofer, Valentin
AU - Senatore, Leonardo
AU - Vlah, Zvonimir
AU - Angulo, Raul
N1 - Funding Information:
We thank Mikhail (Misha) Shaposhnikov for support. V.M. thanks the Stanford Institute for Theoretical Physics for hospitality. L.S. is partially supported by DOE Early Career Award DE-FG02-12ER41854. Z.V. is supported in part by the U.S. Department of Energy contract to SLAC no. DEAC02-76SF00515.
Publisher Copyright:
© 2020 IOP Publishing Ltd and Sissa Medialab.
PY - 2020/1/2
Y1 - 2020/1/2
N2 - Most of the upcoming cosmological information will come from analyzing the clustering of the Large Scale Structures (LSS) of the universe through LSS or CMB observations. It is therefore essential to be able to understand their behavior with exquisite precision. The Effective Field Theory of Large Scale Structures (EFTofLSS) provides a consistent framework to make predictions for LSS observables in the mildly non-linear regime. In this paper we focus on biased tracers. We argue that in calculations at a given order in the dark matter perturbations, highly biased tracers will underperform because of their larger higher derivative biases. A natural prediction of the EFTofLSS is therefore that by simply adding higher derivative biases, highly massive tracers should perform comparably well. We implement this prediction for the halo-halo and the halo-matter power spectra at one loop, and the halo-halo-halo, halo-halo-matter, and halo-matter-matter bispectra at tree-level, and compare with simulations. We find good agreement with the prediction: at z = 0, for all tracers, we are able to match the power spectra up to k = 0.28h Mpc-1 , as well as a small set of about 102 bispectra triangles up to k = 0.17h Mpc-1. We also discuss the limitations of our study and some avenues to pursue to further establish these findings.
AB - Most of the upcoming cosmological information will come from analyzing the clustering of the Large Scale Structures (LSS) of the universe through LSS or CMB observations. It is therefore essential to be able to understand their behavior with exquisite precision. The Effective Field Theory of Large Scale Structures (EFTofLSS) provides a consistent framework to make predictions for LSS observables in the mildly non-linear regime. In this paper we focus on biased tracers. We argue that in calculations at a given order in the dark matter perturbations, highly biased tracers will underperform because of their larger higher derivative biases. A natural prediction of the EFTofLSS is therefore that by simply adding higher derivative biases, highly massive tracers should perform comparably well. We implement this prediction for the halo-halo and the halo-matter power spectra at one loop, and the halo-halo-halo, halo-halo-matter, and halo-matter-matter bispectra at tree-level, and compare with simulations. We find good agreement with the prediction: at z = 0, for all tracers, we are able to match the power spectra up to k = 0.28h Mpc-1 , as well as a small set of about 102 bispectra triangles up to k = 0.17h Mpc-1. We also discuss the limitations of our study and some avenues to pursue to further establish these findings.
KW - Cosmological parameters from LSS
KW - Cosmological perturbation theory
KW - Power spectrum
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U2 - 10.1088/1475-7516/2020/01/009
DO - 10.1088/1475-7516/2020/01/009
M3 - Article
AN - SCOPUS:85081959602
SN - 1475-7516
VL - 2020
JO - Journal of Cosmology and Astroparticle Physics
JF - Journal of Cosmology and Astroparticle Physics
IS - 1
M1 - 009
ER -