Modeling biased tracers at the field level

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Modeling biased tracers at the field level

Marcel Schmittfull, Marko Simonović, Valentin Assassi, and Matias Zaldarriaga

Phys. Rev. D 100, 043514 – Published 8 August 2019

Abstract

In this paper, we test the perturbative halo bias model at the field level. The advantage of this approach is that any analysis can be done without sample variance if the same initial conditions are used in simulations and perturbation theory calculations. We write the bias expansion in terms of modified bias operators in Eulerian space, designed such that the large bulk flows are automatically resummed and not treated perturbatively. Using these operators, the bias model accurately matches the Eulerian density of halos in N-body simulations. The mean-square model error is close to the Poisson shot noise for a wide range of halo masses, and it is rather scale independent, with scale-dependent corrections becoming relevant at the nonlinear scale. In contrast, for the linear bias, the mean-square model error can be higher than the Poisson prediction by factors of up to a few on large scales, and it becomes scale dependent already in the linear regime. We show that by weighting simulated halos by their mass, the mean-square error of the model can be further reduced by up to an order of magnitude, or by a factor of 2 when including 60% mass scatter. We also test the standard Eulerian bias model using the nonlinear matter field measured from simulations and show that it leads to a larger and more scale-dependent model error than the bias expansion based on perturbation theory. These results may be of particular relevance for cosmological inference methods that use a likelihood of the biased tracer at the field level or for initial condition and baryon acoustic oscillation reconstruction that requires a precise estimate of the large-scale potential from the biased tracer density.

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Received 28 November 2018

DOI:https://doi.org/10.1103/PhysRevD.100.043514

Published by the American Physical Society under the terms of the Creative Commons Attribution 4.0 International license. Further distribution of this work must maintain attribution to the author(s) and the published article’s title, journal citation, and DOI.

Published by the American Physical Society

Physics Subject Headings (PhySH)

Cosmological parameters Cosmology Dark energy Dark matter Effective field theory Evolution of the Universe Large scale structure of the Universe Massive compact halo objects Perturbation theory Sky surveys

Galactic halos Galaxies

Astronomical masses & mass distributions

Astrophysical & cosmological simulations Numerical simulations in gravitation & astrophysics Stochastic processes & statistics

Gravitation, Cosmology & AstrophysicsParticles & Fields

Authors & Affiliations

Marcel Schmittfull ¹, Marko Simonović^2,1, Valentin Assassi¹, and Matias Zaldarriaga¹

¹Institute for Advanced Study, Princeton, New Jersey 08540, USA
²Theoretical Physics Department, CERN, 1 Esplanade des Particules, Geneva 23, CH-1211, Switzerland

Article Text

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Issue

Vol. 100, Iss. 4 — 15 August 2019

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Physical Review D

covering particles, fields, gravitation, and cosmology