This study aims to study the effect of reactions and temperature on the drag force coefficient in the process of char combustion. For this purpose, two-dimensional fully resolved simulations are performed using the ghost cell immersed boundary method.Heat and mass transfer, together with the corresponding Stefan flow, is accounted for.Reactive particles with different reaction rates, temperatures and diameters are compared with a non-reactive adiabatic particle and a particle with outflow. For a char particle, results show that reactions tend to increase the drag force, which is converse to the effect observed for non-reactive particles with a pure outflow. This discrepancy is due to the fact that species and temperature distribution play an important role, and both of them can affect the property of the fluid. Hence, a reactive particle cannot be simplified as a particle with only outflow. Based on the current study, a new drag force correlation for a single reactive particle is obtained. The correlation shows a good agreement with the simulation results. A posterior analysis is also performed to verify the accuracy of the correlation.