Hunting Inflaton at FASER

Abstract

We explore a possibility that an inflaton, which drives the cosmological inflation in the early Universe, can be detected by the recently approved FASER at the High-Luminosity LHC (HL-LHC). We consider nonminimal quartic inflation scenario in the minimal U(1)X extension of the Standard Model (SM) with the classical conformal invariance, where the inflaton is identified with the U(1)X Higgs field (φ). By virtue of the classical conformal invariance and the radiative U(1)X symmetry breaking via the Coleman-Weinberg mechanism, the inflationary predictions (in particular, the tensor-to-scaler ratio (r)), the U(1)X coupling (gX) and the U(1)X gauge boson mass (mZ), are all determined by only two free parameters, the inflaton mass (mφ) and its mixing angle (θ) with the SM Higgs field. The FASER can search for the inflaton for the parameter ranges of 0.1 mφ[ GeV] 4 and 10-5 θ 10-3. Because of the direct connection among r, gX and mZ, the Z boson resonance search at the HL-LHC and the future measurement of the primordial gravitational wave are complementary to the inflaton search at the FASER.