Abstract
In this paper, we generalize Coleman–Weinberg (CW) inflation in grand unified theories (GUTs) such as text {SU}(5) and text {SO}(10) by means of considering two complex singlet fields with conformal invariance. In this framework, inflation emerges from a spontaneously broken conformal symmetry. The GUT symmetry implies a potential with a CW form, as a consequence of radiative corrections. The conformal symmetry flattens the above VEV branch of the CW potential to a Starobinsky plateau. As a result, we obtain n_{s}sim 1-frac{2}{N} and rsim frac{12}{N^2} for Nsim 50–60 e-foldings. Furthermore, this framework allow us to estimate the proton lifetime as tau _{p}lesssim 10^{40} years, whose decay is mediated by the superheavy gauge bosons. Moreover, we implement a type I seesaw mechanism by weakly coupling the complex singlet, which carries two units of lepton number, to the three generations of singlet right handed neutrinos (RHNs). The spontaneous symmetry breaking of global lepton number amounts to the generation of neutrino masses. We also consider non-thermal leptogenesis in which the inflaton dominantly decays into heavy RHNs that sources the observed baryon asymmetry. We constrain the couplings of the inflaton field to the RHNs, which gives the reheating temperature as 10^{6}text { GeV}lesssim T_{R}<10^{9} GeV.
Highlights
Thereafter, we study the dominant decay of inflaton into heavy right handed neutrinos (RHNs) producing non-thermal leptogenesis
Coleman–Weinberg inflation [11] has been a successful and realistic model based on grand unified theories (GUTs) and is consistent with the current Planck data with r 0.02 [15]
We have further generalized the framework of CW inflation with an additional conformal symmetry
Summary
This framework allow us to estimate the proton lifetime as τp 1040 years, whose decay is mediated by the superheavy gauge bosons. I seesaw mechanism by weakly coupling the complex singlet, which carries two units of lepton number, to the three generations of singlet right handed neutrinos (RHNs). The spontaneous symmetry breaking of global lepton number amounts to the generation of neutrino masses. We consider non-thermal leptogenesis in which the inflaton dominantly decays into heavy RHNs that sources the observed baryon asymmetry. We constrain the couplings of the inflaton field to the RHNs, which gives the reheating temperature as 106 GeV TR < 109 GeV
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