Primordial Power Spectrum features and fNL constraints

Abstract

The simplest models of inflation predict small non-gaussianities and a featureless power spectrum. However, there exist a large number of well-motivated theoretical scenarios in which large non-gaussianties could be generated. In general, in these scenarios the primordial power spectrum will deviate from its standard power law shape. We study, in a model-independent manner, the constraints from future large scale structure surveys on the local non-gaussianity parameter f NL when the standard power law assumption for the primordial power spectrum is relaxed. If the analyses are restricted to the large scale-dependent bias induced in the linear matter power spectrum by non-gaussianites, the errors on the f NL parameter could be increased by 60\% when exploiting data from the future DESI survey, if dealing with only one possible dark matter tracer. In the same context, a nontrivial bias |δ f NL| 2.5 could be induced if future data are fitted to the wrong primordial power spectrum. Combining all the possible DESI objects slightly ameliorates the problem, as the forecasted errors on f NL would be degraded by 40\% when relaxing the assumptions concerning the primordial power spectrum shape. Also the shift on the non-gaussianity parameter is reduced in this case, |δ f NL| 1.6. The addition of Cosmic Microwave Background priors ensure robust future f NL bounds, as the forecasted errors obtained including these measurements are almost independent on the primordial power spectrum features, and |δ f NL| 0.2, close to the standard single-field slow-roll paradigm prediction.