The NANOGrav 15 yr Data Set: Impacts of Customized Chromatic Noise Models on Gravitational Wave Analyses

Abstract

We report updated nHz gravitational wave (GW) significance, characterization, and interpretations using the customized chromatic-noise models (CNMs) developed in Larsen, Baier et al. (2026). for the NANOGrav 15-year data set. We find increased evidence for the Hellings-Downs (HD) correlation signature of the stochastic gravitational wave background (GWB), with a Bayes factor of 157114 for HD-correlations over a common uncorrelated red-noise process using a power-law model with 14 Fourier modes. We find this 8× increase in Bayes factor from Agazie et al. (2023a) is a result of improved noise mitigation. Assuming an analytic null distribution for the frequentist interpulsar correlation statistic, this corresponds to a slightly more significant measurement from 3.16σ to 3.32σ against the no-correlation scenario. Spectral inference with CNMs brings the power-law GWB amplitude down to A GWB = 2.1+0.6-0.5×10-15 at fixed γ GWB = 13/3. In a varied-γ analysis, the spectral index increases to γ GWB=3.5+0.7-0.6. We report updates on an all-sky continuous gravitational wave (CW) search as well as select targeted searches and calculate a 3.2× larger detection volume for the NANOGrav detector. With CNMs, we find reduced evidence for a non-Einsteinian, scalar-transverse mode of gravity. Finally, we reinterpret the GWB first with the assumption of an astrophysical background sourced by SMBHBs and then assuming the more exotic origins of cosmic inflation, a first-order cosmological phase transition, and stable cosmic strings. Under both the SMBHB hypothesis and the cosmological hypotheses, we see only marginal shifts in model parameter posteriors which are consistent with the slightly quieter and steeper power-law GWB spectrum.