Dark QCD Origin of the NANOGrav Signal and Self-Interacting Dark Matter

Abstract

The NANOGrav 15-year stochastic gravitational wave background (SGWB) amplitude A yr ≈ 2.4 × 10-15 lies at the upper edge of population synthesis predictions for supermassive black hole binaries (SMBHBs), motivating exploration of additional cosmological sources. We present a phenomenological framework based on an SU(3)D gauge theory that can simultaneously accommodate the gravitational wave signal and resolve small-scale structure anomalies via Self-Interacting Dark Matter (SIDM). The dark matter candidate is a heavy dark baryon = QQQ with mass m ≈ 40~GeV, which self-interacts through a light pseudo-dilaton d md ≈ 20--50~MeV as a pseudo-Goldstone boson of approximate scale invariance arising in near-conformal gauge theories with Nf 6--8 light flavors. A first-order phase transition at the MeV scale, enabled by walking dynamics near the conformal window, produces gravitational waves in the PTA band. For representative parameters Tn ≈ 5--6~MeV, α 500--1000, β/H* 30--50, the model provides a fit to NANOGrav data comparable to SMBHB while naturally connecting the gravitational wave amplitude to the dark matter relic density through entropy dilution D ≈ α3/4. We present explicit calculations of the bounce action, bubble wall velocity, and N eff, demonstrating that the benchmark parameters are theoretically consistent and cosmologically safe ( N eff 0.1 for mπ > 2md). The distinctive spectral shape (f3 f-4) provides a robust prediction testable with future PTAs.