A data-driven prediction for the primordial deuterium abundance

Abstract

We predict the primordial deuterium abundance using a novel, fully data-driven approach, where we use Gaussian process regression to fit experimental nuclear reaction data for d,(d,n)3He, d,(d,p)t, and d(p,γ)3He, three reactions to which the primordial deuterium abundance is most sensitive. Using the Planck determination of the baryon density, we predict 105×D/H = 2.4420.040 in standard Big Bang Nucleosynthesis, 1.70σ below the Cooke et al. measurement. Our result is consistent with predictions relying on first principles calculations of the deuterium burning cross sections. With the inferred baryon density from a combined fit to Planck, ACT DR6, and SPT-3G D1, this discrepancy worsens to 1.98σ. We validate our approach and confirm that Gaussian processes make unbiased D/H predictions with appropriately-sized uncertainties. We repeat our validation tests for low-degree polynomial fits, a technique used in previous analyses, and find that they systematically over-predict D/H. Our results highlight the need for improved measurements of the d,(d,n)3He and d,(d,p)t S-factors at energies between 0.1 and 0.6 MeV.