Gravitational waves from cosmic strings in Froggatt-Nielsen flavour models

Gravitational waves (GWs) are a powerful probe of the earliest moments in the Universe, enabling us to test fundamental interactions at energy scales beyond the reach of laboratory experiments. In this work, we assess the GW capability to probe the origin of the flavour sector of the Standard Model (SM). Within the context of Froggatt-Nielsen models of fermion masses and mixing based on a gauged U(1) flavour symmetry, we investigate the formation of cosmic strings and the resulting GW background (GWB), estimating the sensitivity to the model's parameter space of future GW experiments. Comparing these results with the bounds from low-energy flavour observables, we find that these two types of experimental probes of the model are nicely complementary. Flavour physics observables can probe low to intermediate symmetry-breaking scales v phi, while future GW experiments are sensitive to the opposite regime, for which the string tension is large enough to yield sizeable GW signals, and in the long run can set an upper limit on the scale as stringent as v phi less than or similar to 109 GeV. In certain scenarios, the combination of flavour constraints and future GW bounds can bring about a complete closure of the available parameter space, which illustrates how GWB searches can play an important role in testing the origin of the SM flavour sector even if that occurs at ultra-high energies.