Computing Nonlinear Power Spectra Across Dynamical Dark Energy Model Space with Neural ODEs
Abstract
I show how to compute the nonlinear power spectrum across the entire w(z) dynamical dark energy model space. Using synthetic data, I train a neural ordinary differential equation (ODE) to infer the evolution of the nonlinear matter power spectrum as a function of the background expansion and mean matter density across 9 \ Gyr of cosmic evolution. After training, the model generalises to any dynamical dark energy model parameterised by w(z). With little optimisation, the neural ODE is accurate to within 4\% up to k = 5 \ h Mpc-1. Unlike simulation rescaling methods, neural ODEs naturally extend to summary statistics beyond the power spectrum that are sensitive to the growth history.
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