S. Belov, T. Parmenter, T. Arber, D. Kolotkov, F. Reale, T. Goffrey

Hot solar coronal loops, such as flaring loops, reach temperatures where the thermal transport becomes non-local. This occurs when the mean-free-path of electrons can no longer be assumed to be small. Using a modified version of the Lare2d code, we study the evolution of flare-heated coronal loops under three thermal transport models: classical Spitzer-Harm (SH), a flux-limited local model (FL), and the non-local Schurtz-Nicolai-Basquet (SNB) model. The SNB model is used extensively in laser-plasma studies. It has been benchmarked against accurate non-local Vlasov-Fokker-Planck models and proven to be the most accurate non-local model which can be applied on fluid time-scales. Analysis of the density-temperature evolution cycles near the loop apex reveals a distinct evolutionary path for the SNB model, with higher temperatures and lower densities than local models. During energy deposition, the SNB model produces a more localised and intense temperature peak at the apex due to heat flux suppression, which also reduces chromospheric evaporation and results in lower post-flare densities. EUV emission synthesis shows that the SNB model yields flare light curves with lower peak amplitudes and smoother decay phases. We also find that non-local transport affects equilibrium loop conditions, producing hotter and more rarefied apexes. These findings emphasise the need to account for non-local conduction in dynamic solar phenomena and highlight the potential of the SNB model for improving the realism of flare simulations. Flux-limited conduction models cannot reproduce the results of non-local transport covered by the SNB model.