Signatures of anisotropic sources in the squeezed-limit bispectrum of the cosmic microwave background

Abstract

The bispectrum of primordial curvature perturbations in the squeezed configuration, in which one wavenumber, k3, is much smaller than the other two, k3 k1≈ k2, plays a special role in constraining the physics of inflation. In this paper we study a new phenomenological signature in the squeezed-limit bispectrum: namely, the amplitude of the squeezed-limit bispectrum depends on an angle between k1 and k3 such that Bζ(k1, k2, k3) 2 ΣL cL PL( k1 · k3) Pζ(k1)Pζ(k3), where PL are the Legendre polynomials. While c0 is related to the usual local-form f NL parameter as c0=6f NL/5, the higher-multipole coefficients, c1, c2, etc., have not been constrained by the data. Primordial curvature perturbations sourced by large-scale magnetic fields generate non-vanishing c0, c1, and c2. Inflation models whose action contains a term like I(φ)2 F2 generate c2=c0/2. A recently proposed "solid inflation" model generates c2 c0. A cosmic-variance-limited experiment measuring temperature anisotropy of the cosmic microwave background up to max=2000 is able to measure these coefficients down to δ c0=4.4, δ c1=61, and δ c2=13 (68% CL). We also find that c0 and c1, and c0 and c2, are nearly uncorrelated. Measurements of these coefficients will open up a new window into the physics of inflation such as the existence of vector fields during inflation or non-trivial symmetry structure of inflaton fields. Finally, we show that the original form of the Suyama-Yamaguchi inequality does not apply to the case involving higher-spin fields, but a generalized form does.