Litcius/Paper detail

Effective field theory of chiral gravitational waves

Katsuki Aoki, Tomohiro Fujita, Ryodai Kawaguchi, Kazuki Yanagihara

2026Journal of Cosmology and Astroparticle Physics6 citationsDOIOpen Access PDF

Abstract

Abstract When a (non-)Abelian gauge field acquires an isotropic background configuration during inflation, strong gravitational waves (GWs) with parity-violating polarization, known as chiral GWs, can be produced in addition to the intrinsic unpolarized GWs. However, previous studies have analyzed individual models, leaving the generality of this phenomenon unclear. To perform a model-independent analysis, we construct an effective field theory (EFT) of chiral GWs by extending the EFT of inflation and incorporating gauge fields. The resulting action unifies inflationary models with a SU(2) gauge field, such as chromo-natural inflation and gauge-flation, and ones with a triplet of U(1) gauge fields, systematically encompassing all possible GW production mechanisms consistent with the symmetry breaking induced by the gauge field background. We find that chiral GWs are generically and inevitably produced, provided that the effective energy density of the background gauge field is positive and the gauge kinetic function is not fine-tuned to a specific time dependence. This EFT offers a useful foundation for future phenomenological studies as well as for deepening our theoretical understanding of chiral GWs.

Topics & Concepts

PhysicsTheoretical physicsGauge theoryGauge anomalyEffective field theoryIntroduction to gauge theoryGauge bosonGauge (firearms)Inflation (cosmology)Symmetry breakingGauge symmetryChiral symmetry breakingGravitational waveQuantum electrodynamicsField (mathematics)Hamiltonian lattice gauge theorySpontaneous symmetry breakingEffective actionStandard Model (mathematical formulation)GravitationChiral anomalyKinetic termHiggs fieldSupersymmetric gauge theoryClassical mechanicsSymmetry (geometry)Quantum mechanicsParticle physicsGoldstone bosonCosmology and Gravitation TheoriesPulsars and Gravitational Waves ResearchBlack Holes and Theoretical Physics