Probing a nonminimal coupling through superhorizon instability and secondary gravitational waves

Abstract

In this paper, we investigate the impact of scalar fluctuations () non-minimally coupled to gravity, 2 R, as a potential source of secondary gravitational waves (SGWs). Our study reveals that when reheating EoS < 1/3 and 1/6 or > 1/3 and 1/6, the super-horizon modes of scalar field experience a Tachyonic instability during the reheating phase. Such instability causes a substantial growth in the scalar field amplitude leading to pronounced production of SGWs in the low and intermediate-frequency ranges that are strong enough to be detected by Planck and future gravitational wave detectors. Such growth in super-horizon modes of the scalar field and associated GW production may have a significant effect on the strength of the tensor fluctuation at the Cosmic Microwave Background (CMB) scales (parametrized by r) and the number of relativistic degrees of freedom (parametrized by ) at the time of CMB decoupling. To prevent such overproduction, the PLANCK constraints on tensor-to-scalar ratio r ≤ 0.036 and ≤ 0.284 yield a strong lower bound on for < 1/3, and upper bound on the value of for > 1/3. Taking into account all the observational constraints we found the value of should be 0.02 for =0, and 4.0 for ≥ 1/2 for a wide range of reheating temperature within 10-2 1014 GeV, and for a wide range of inflationary energy scales. Further, as one approaches towards 1/3, the value of remains unconstrained. Finally, we identify the parameter regions in (,) plane which can be probed by the upcoming GW experiments namely BBO, DECIGO, LISA, and ET.