Dark Energy Survey Year 3 results: Constraints on extensions to Λ CDM with weak lensing and galaxy clustering

We constrain six possible extensions to the. cold dark matter (CDM) model using measurements from the Dark Energy Survey's first three years of observations, alone and in combination with external cosmological probes. The DES data are the two-point correlation functions of weak gravitational lensing, galaxy clustering, and their cross-correlation. We use simulated data vectors and blind analyses of real data to validate the robustness of our results to astrophysical and modeling systematic errors. In many cases, constraining power is limited by the absence of theoretical predictions beyond the linear regime that are reliable at our required precision. The.CDM extensions are dark energy with a time-dependent equation of state, nonzero spatial curvature, additional relativistic degrees of freedom, sterile neutrinos with eV-scale mass, modifications of gravitational physics, and a binned s 8ozTHORN model which serves as a phenomenological probe of structure growth. For the time-varying dark energy equation of state evaluated at the pivot redshift we find (w(p), w(a)) = (-0.99(-0.17)(+0.28), -0.9 +/- 1.2) at 68% confidence with z(p) = 0.24 from the DES measurements alone, and (w(p), w(a)) = (-1.03(-0.03)(+0.04), -0.4(-0.3)(+0.4)) with z(p) = 0.21 for the combination of all data considered. Curvature constraints of Omega(k) = 0.0009 +/- 0.0017 and effective relativistic species N-eff = 3.10(-0.16)(+0.15) are dominated by external data, though adding DES information to external low-redshift probes tightens the Omega(k) constraints that can be made without cosmic microwave background observables by 20%. For massive sterile neutrinos, DES combined with external data improves the upper bound on the mass m(eff) by a factor of 3 compared to previous analyses, giving 95% limits of (Delta N-eff, m(eff)) <= (0.28, 0.20 eV) when using priors matching a comparable Planck analysis. For modified gravity, we constrain changes to the lensing and Poisson equations controlled by functions Sigma(k, z) = Sigma(0)Omega(Lambda)(z)/Omega(Lambda,0) and mu(k,z) = mu(0)Omega(Lambda)(z)/Omega(Lambda,0), respectively, to Sigma(0) = 0.6(-0.5)(+0.4) from DES alone and (Sigma(0),mu(0)) = (0.04 +/- 0.05, 0.08(-0.19)(+0.21)) for the combination of all data, both at 68% confidence. Overall, we find no significant evidence for physics beyond Lambda CDM.