Abstract:
We investigate the possibility of constraining primordial non-Gaussianity using the 3D bispectrum of the Lyman (Ly)-α forest. The strength of the quadratic non-Gaussian correction to an otherwise Gaussian primordial gravitational field is assumed to be dictated by a single parameter fNL. We present the first prediction for bounds on fNL using Ly-α flux spectra along multiple lines of sight. The 3D Ly-α transmitted flux field is modeled as a biased tracer of the underlying matter distribution sampled along 1D skewers corresponding to quasar sight lines. The precision to which fNL can be constrained depends on the survey volume, pixel noise, and aliasing noise (arising from discrete sampling of the density field). We consider various combinations of these factors to predict bounds on fNL. We find that in an idealized situation of full sky survey and negligible Poisson noise one may constrain fNL∼23 in the equilateral limit. Assuming a Ly-α survey covering large parts of the sky (kmin=8×10−4 Mpc−1) and with a quasar density of ¯n=5×10−3 Mpc−2, it is possible to constrain fNL∼100 for equilateral configurations. The possibility of measuring fNL at a precision comparable to large scale structure studies maybe useful for joint constraining of inflationary scenarios using different data sets.