Measuring primordial non-gaussianity without cosmic variance

TL;DR

This paper introduces a new method to measure primordial non-Gaussianity by correlating biased and unbiased tracers of large-scale structure, effectively eliminating cosmic variance and significantly improving detection sensitivity.

Contribution

It proposes an innovative cosmic variance-free approach using cross-correlation of tracers, surpassing traditional power spectrum limitations in detecting non-Gaussianity.

Findings

Error reduction factor up to seven for ideal surveys.

Method eliminates cosmic variance by cross-correlating tracers.

Potential for high signal-to-noise detection of non-Gaussianity.

Abstract

Non-gaussianity in the initial conditions of the universe is one of the most powerful mechanisms to discriminate among the competing theories of the early universe. Measurements using bispectrum of cosmic microwave background anisotropies are limited by the cosmic variance, i.e. available number of modes. Recent work has emphasized the possibility to probe non-gaussianity of local type using the scale dependence of large scale bias from highly biased tracers of large scale structure. However, this power spectrum method is also limited by cosmic variance, finite number of structures on the largest scales, and by the partial degeneracy with other cosmological parameters that can mimic the same effect. Here we propose an alternative method that solves both of these problems. It is based on the idea that on large scales halos are biased, but not stochastic, tracers of dark matter: by correlating a highly biased tracer of large scale structure against an unbiased tracer one eliminates the cosmic variance error, which can lead to a high signal to noise even from the structures comparable to the size of the survey. The square of error improvement on non-gaussianity parameter f_nl relative to the power spectrum method scales as Pn/2, where P and n is the power spectrum and the number density of the biased tracer, respectively. For an ideal survey out to z=2 the error reduction can be as large as a factor of seven, which should guarantee a detection of non-gaussianity from an all sky survey of this type. The improvements could be even larger if high density tracers that are sensitive to non-gaussianity can be identified and measured over a large volume.