This thesis focuses on vacuum GWs, the tensorial counterpart of scalar quantum fluctuations that seeded galaxies. Their renormalized energy density connects to the observed abundance of the first light elements, providing a pathway to constrain vacuum GWs without direct detection. Careful renormalization of the divergences arising in computing the energy density of vacuum GWs reveals that they only renormalize background quantities and do not act as an additional radiation-like species. We stress that a fundamental role in reaching this conclusion is played by properly following through with the renormalization procedure, which is not a way to "sweep divergences under the rug" by introducing a hard cutoff in divergent integrals. Instead, it is a well-defined method to absorb UV-divergent contributions and extract meaningful physical predictions.

• early universe
• gravitational waves
• primordial non-gaussianity
• quantum field theory
• renormalization

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