Abstract
Motivated by the flavored Peccei-Quinn symmetry for unifying flavor physics and string theory, we investigate a supersymmetric extension of standard model (SM) for an explanation of inflation and leptogenesis by introducing $U(1)$ symmetries such that the $U(1)$-$[gravity]^2$ anomaly-free condition together with the SM flavor structure demands additional sterile neutrinos as well as no axionic domain-wall problem. Such additional neutrinos may play a crucial role as a bridge between leptogenesis and new neutrino oscillations along with high energy cosmic events. In a realistic moduli stabilization, we show that the moduli backreaction effect on the inflationary potential leads to the energy scale of inflation with the inflaton mass in a way that the power spectrum of the curvature perturbation and the scalar spectral index are to be well fitted with the latest Planck observation. We suggest that a new leptogenesis scenario could naturally be implemented via Affleck-Dine mechanism. So we show that the resultant baryon asymmetry, constrained by the sum of active neutrino masses and new high energy neutrino oscillations, crucially depends on the reheating temperature $T_{\rm reh}$. And we show that the model has a preference on $T_{\rm reh}\sim10^3$ TeV, which is compatible with the required $T_{\rm reh}$ to explain the baryon asymmetry of the Universe.
Highlights
The standard model (SM) of particle physics has been successful in describing properties of known matter and forces to a great precision until now, but we are far from satisfied since it suffers from some problems or theoretical arguments that have not been solved yet
In the presence of SUGRA, SUSYinf is gauged, and its corresponding Goldstino is eaten by the gravitino via the super-Higgs mechanism, leaving behind the approximate global symmetry SUSYvis, which is explicitly broken by SUGRA and its corresponding uneaten
In the presence of SUGRA, the SUSYinf is gauged, and its corresponding Goldstino is eaten by the gravitino via the super-Higgs mechanism, leaving behind the approximate global symmetry SUSYvis, which is explicitly broken by SUGRA and its corresponding uneaten Goldstino as a propagating d.o.f
Summary
The standard model (SM) of particle physics has been successful in describing properties of known matter and forces to a great precision until now, but we are far from satisfied since it suffers from some problems or theoretical arguments that have not been solved yet These include the following: inclusion of gravity in gauge theory, instability of the Higgs potential, cosmological puzzles of matter-antimatter asymmetry, dark matter, dark energy, and inflation, and flavor puzzle associated with the SM fermion mass hierarchies, their mixing patterns with the CP-violating phases, and the strong CP problem. Enough, the pseudo-Dirac mass splittings, suggested from the new neutrino oscillations along with high-energy cosmic events [3], strongly indicate the existence of lepton-number violation, which is a crucial ingredient of the present leptogenesis scenario. The resultant baryon asymmetry is constrained by the cosmological observable (i.e., the sum of active neutrino masses) with the new high-energy neutrino oscillations and crucially depends on the reheating temperature, which depends on gravitational and nongravitational decays of the inflaton and waterfall field. Corresponding uneaten Goldstino gives masses mainly to all the supersymmetric SM superpartners in the visible sector
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