Axion-Sourced Gravitational Waves in B\!-\!L Hybrid Inflation

Abstract

Minimal supersymmetric B\!-\!L hybrid inflation predicts a negligible vacuum tensor-to-scalar ratio r vac 10-8 due to its extremely flat potential. In this letter, we show that adding a spectator pseudoscalar axion-like field coupled to the U(1)B\!-\!L gauge sector via a Chern-Simons term circumvents this suppression. The rolling axion triggers a tachyonic instability for one gauge field helicity, exponentially amplifying gauge fluctuations. These sourced modes generate a stochastic gravitational-wave background with tensor power spectrum PT src e4πξ/ξ6, where ξ= αϕ / (2 fa H) is the gauge-field instability parameter. For ξ3.3--3.6, the tensor-to-scalar ratio reaches r10-3, within the sensitivity of LiteBIRD. For ξ3.6, the gravitational-wave spectrum develops a peaked shape that enters the LISA sensitivity band (peaking at frequencies around 10-3 Hz) with an amplitude h2Ω GW2.5×10-13. The mechanism predicts chiral gravitational waves, a broken consistency relation r=16ε, and a distinctive r--Ω GW correlation that could be tested by future CMB and interferometer observations.