MG-NECOLA: A Field-Level Emulator for f(R) Gravity and Massive Neutrino Cosmologies

Abstract

Accurate modeling of non-linear gravitational dynamics is essential for constraining extensions to the standard cosmological model using large-scale structure observations. While high-resolution N-body simulations provide the required fidelity, they are computationally prohibitive for the large ensembles needed to analyze Modified Gravity (MG) scenarios. We present MG-NECOLA, a field-level emulator based on a convolutional neural network that upgrades fast, approximate MG-PICOLA simulations to near--N-body accuracy at a fraction of the computational cost. Trained on a suite of QUIJOTEMG simulations for f(R) gravity, MG-NECOLA achieves nearly sub-percent accuracy ( 1\%) in both the matter power spectrum and bispectrum up to k 1~h\,Mpc-1. Crucially, although being trained on a fixed cosmology, the network generalizes robustly to cosmologies outside its training manifold keeping the error below 5\%. It successfully recovers the General Relativity limit () without introducing spurious MG signals and accurately captures the power suppression induced by massive neutrinos (M ≤ 0.4 eV), despite being trained on cosmologies with massless neutrinos. The pipeline delivers a speed-up factor of 1500× relative to full N-body runs, generating a high-fidelity realization in O(103) CPU seconds compared to O(106) for the baseline. This accuracy-efficiency trade-off establishes MG-NECOLA as a powerful tool for generating the massive mock catalogs required for next-generation galaxy surveys.