Molecular dynamics (MD) calculation is an important computational method for materials science and engineering. To obtain meaningful results from MD simulations for harsh environments, one has to prepare a quality potential model that works appropriately not only in equilibrium states but also in non-equilibrium states. We have recently developed a systematic method to construct (i) two-body potentials [T. Oda, W.J. Weber, H. Tanigawa, Comp. Mater. Sci. 111 (2016) 53] and (ii) embedded-atom method (EAM) potentials [T. Oda, submitted]. In this method, potential functions are expanded with cosine/sine series in reference to energies, forces and stresses evaluated by first-principles calculations. In the present study, using this method, we aim to construct potential models of a metal (bcc-Fe) and a metal oxide (Li₂O) for radiation environments. For this aim, results of first-principles molecular dynamics calculations of several atomic collision events are included in the reference data. MD simulation results with the constructed potential models show a reasonable agreement with available experimental data on fundamental material properties and threshold displacement energies. It is indicated that the method can effectively construct a potential model for MD simulations of harsh environments.