No-go Theorem for Cosmological Parity Violation

Abstract

A no-go theorem for parity-violation in even D-dimensional spacetimes invariant under ISO(d) and dilatations (as well as the implications for odd D) is derived. For the case of real massless scalar and gravitons (as well as any massless even integer spin-s field) at I+, the reality of wavefunction coefficients in Fourier space to all orders in perturbation theory (any order in loops) coming from a local, unitary, IR- and UV-finite theory, which start from the initial -invariant Bunch-Davies state in the infinite past, is proven. From this it is inferred that a parity-odd correlator with any massless scalar fields and even integer spin-s fields vanishes in the presence of any number of interactions of massless fields. The same is true for correlators with an even number of conformally-coupled and massless odd integer spin-s external fields, which is used to derive the cosmological analogue of Furry's theorem. The fundamental implications of symmetry for theories with chemical potentials, such as Chern-Simons and Axion inflation, is also discussed. Given the recent interest in parity-violation coming from observational claims of parity-violation detection, these results provide clear constraints on parity-violating models of inflation and establish the measurement of any parity-odd correlator as an exceptionally sensitive probe of new physics beyond vanilla inflation.