Approximate gauge independence of the induced gravitational wave spectrum

Gravitational waves (GWs) induced by scalar curvature fluctuations are an important source of the cosmological GW background and a crucial counterpart of the primordial black hole scenario. However, doubts have been cast on the theoretically predicted induced GW spectrum due to its seeming gauge dependence. In this paper, we shed light on the gauge dependence issue of the induced GW spectrum in general cosmological backgrounds. First, inspired by the Hamiltonian formalism we provide very simple formulas for the tensor modes at second order in cosmological perturbation theory. We also emphasize the difference between observable and gauge invariant variables. Second, we argue that the Newton (or shearfree) gauge is suitable for both the calculation of induced GWs and the physical interpretation. We then show that, most notably, the induced GW spectrum is invariant under a set of reasonable gauge transformations, i.e., physically well behaved on small scales, once the source term has become inactive. This includes the commonly used flat, constant Hubble and synchronous gauges but excludes the comoving slicing gauge. We also show that a particular solution of the GW equation in a dust dominated universe while the source term is active can be gauged away by a small change of gauge.

Automated summary

This paper discusses the gauge dependence issue of induced gravitational wave spectrum in cosmological backgrounds, providing simple formulas and highlighting the difference between observable quantities and gauge-invariant variables. It suggests that the Newton gauge is suitable for calculations and interpretations of induced gravitational waves, and shows that the spectrum remains invariant under reasonable gauge transformations when the source term becomes inactive.