Damghan University Press Iranian Journal of Astronomy and Astrophysics 2322-4924 12 3 2025 12 22 Numerical Modeling of the Solar Wind: Fluid, Kinetic, and Hybrid Approaches 209 225 2023 10.22128/ijaa.2025.3140.1229 EN Somayeh Taran Faculty of Physics, University of Tabriz, PO Box 51666-16471, Tabriz, Iran 0000-0001-7101-7449 Journal Article 2025 11 11 This paper provides a comprehensive overview of the numerical methods used to model the solar wind, integrating fluid, kinetic, and hybrid perspectives. Beginning with the foundations of solar wind theory and the development of magnetohydrodynamic (MHD) models, we discuss how fluid-based formulations enable the simulation of global structures such as coronal mass ejections, shocks, and large-scale variations in the heliospheric magnetic field. To address processes that fall outside the scope of MHD, we examine kinetic modeling based on the Vlasov–Maxwell equations, emphasizing its capability to reproduce non-Maxwellian particle distributions, wave–particle interactions, temperature anisotropies, and collisionless heating. Hybrid approaches that merge MHD with kinetic techniques are highlighted as essential tools for capturing the multi-scale nature of the solar wind, particularly in regions where macroscopic flows couple to microphysical dynamics. The paper further reviews major numerical strategies used in solar wind simulations, comparing explicit and implicit time integration, adaptive mesh refinement, Particle-in-Cell (PIC) methods, and semi-Lagrangian approaches. Key stability considerations—including boundary-condition selection, the Courant–Friedrichs–Lewy (CFL) constraint, appropriate spatial and velocity-space resolution, and the targeted use of artificial diffusion—are discussed in relation to their impact on accuracy and robustness. Example simulations demonstrate the ability of advanced models to reproduce observed proton and electron temperature profiles \textbf{from the Sun out to 1AU}. Overall, numerical modeling plays a central role in interpreting solar wind observations and predicting space-weather conditions, and ongoing advances in computational methods continue to strengthen our understanding of heliospheric plasma dynamics. Solar Wind Numerical solution MHD Kinetic https://ijaa.du.ac.ir/article_2023_c85915c5d14c3c4c5b566aed401a1c95.pdf