"Finite" Non-Gaussianities and Tensor-Scalar Ratio in Large Volume Swiss-Cheese Compactifications

TL;DR

This paper explores non-Gaussianities and tensor-scalar ratios in large volume Swiss-Cheese Calabi-Yau compactifications, showing how specific corrections and instanton effects can produce finite non-linear parameters and observable cosmological signatures.

Contribution

It introduces a detailed analysis of non-Gaussianities and tensor-scalar ratios in type IIB compactifications, incorporating alpha' corrections and instanton effects, with new predictions for f_{NL} and r.

Findings

Finite f_{NL} values (~0.01-0.03) achieved in specific volume and instanton scenarios.

Tensor-scalar ratio r ~ 10^{-3} with slight scale invariance breaking.

Possible axionic inflaton as dark matter and dark energy candidate.

Abstract

Developing on the ideas of (section 4 of) [1] and [2] and using the formalisms of [3] and [4], after inclusion of perturbative and non-perturbative alpha' corrections to the Kaehler potential and (D1- and D3-) instanton generated superpotential, we show the possibility of getting finite values for the non-linear parameter f_{NL} while looking for non-Gaussianities in type IIB compactifications on orientifolds of the Swiss Cheese Calabi-Yau WCP^4[1,1,1,6,9] in the L(arge) V(olume) S(cenarios) limit. First we show that in the context of multi-field slow-roll inflation, for the Calabi-Yau volume V~10^5 and D3-instanton number n^s~10 along with N_e~18, one can realize f_{NL}~0.03, and for Calabi-Yau volume V~10^6 with D3-instanton number n^s~10 resulting in number of e-foldings N_e~60, one can realize f_{NL}~0.01. Further we show that with the slow-roll conditions violated and for the number of the D3-instanton wrappings n^s ~O(1), one can realize f_{NL} ~O(1). Using general considerations and some algebraic geometric assumptions, we show that with requiring a "freezeout" of curvature perturbations at super horizon scales, it is possible to get tensor-scalar ratio r ~O(10^{-3}) with the loss of scale invariance |n_R-1|=0.01 and one can obtain f_{NL} ~O(10^{-2}) as well in the context of slow-roll inflation scenarios in the same Swiss-Cheese setup. For all our calculations the large values of the genus-zero Gopakumar-Vafa invariants for compact projective varieties, play in important role. We also make some observations pertaining to the possibility of the axionic inflaton also being a cold dark matter candidate as well as a quintessence field used for explaining dark energy.