We extend our super-resolution and emulation framework for cosmological dark matter simulations to include hydrodynamics. We present a two-stage deep learning model to emulate high-resolution (HR-HydroSim) baryonic fields from low-resolution (LR-HydroSim) simulations at redshift z = 3. The method takes as inputs an LR-HydroSim and the high-resolution initial conditions (HR-HydroICs). First, the model stochastically generates high-resolution baryonic fields from the LR-HydroSim. Second, a deterministic emulator refines these fields using HR-HydroICs to reconstruct small-scale structures including displacement, velocity, internal energy, and gas/star classification. Trained on paired low- and high-resolution simulations produced with MP-Gadget, the model captures small-scale structures of the intergalactic medium and %Lyman-α forest observables down to the 100 kpc pressure smoothing scale relevant to the Lyman-α forest. The model achieves subpercent error for overdensity, temperature, velocity, and optical depth fields, a mean relative error of 1. 07\% in the large-scale flux power spectrum (\ (k < 3 10^-2\ s/km\) ), and less than 10\% error in the flux probability distribution function. Notably, the two-stage model reduces the compute time by a factor of 450 compared to full smoothed particle hydrodynamics at the same resolution. This work demonstrates the potential of this framework as a powerful and efficient tool for generating high-resolution fields offering fast and accurate alternatives to traditional cosmological hydrodynamic simulations and enabling large-volume mock datasets for next-generation cosmological surveys.
Hafezianzadeh et al. (Tue,) studied this question.