Ever since the discovery of superconductivity in Yttrium Barium Copper Oxide (YBa2Cu3O7), it became clear that Bardeen-Cooper-Schrieffer (BCS) theory was insuf-ficient in explaining its superconductivity, leading many theoretical physicists to pro-pose their own high-temperature superconductivity theories. In recent years, calcula-tions involving a combination of BCS theory and first-principle calculations led to the discovery of superconductivity in some superhydride materials, which was later veri-fied by experiments. This led to many physicists reconsidering whether BCS theory could explain superconductivity in some superconducting materials or not. In this thesis, we compute the electron and phonon properties of H3S and FeSe using a combination of the first principle density functional theory and BCS theory and dis-cuss their superconducting properties. Experimental H3S analysis shows that its su-perconducting temperature peaks at around 150 GPa and decreases as pressure in-creases further; however, our theoretical calculations do not find this phenomenon. Through investigating references, we discover that incorporating the anharmonic effect into calculations causes results to match up more with the experiments. In our FeSe computations, we include the Van der Waals effect due to the material’s layered struc-ture, but the resulting superconducting temperatures remain much lower than the ex-perimental value (8.5 K). Regarding this result, we concluded from references that the inclusion of the Wannier functions (GW method) may increase the calculated Tc as well as explain its superconductivity. Through computing the specific heat and com-paring it with the experiment, we evaluate the electron-phonon coupling strength of FeSe by empirical formulae and successfully evaluate a superconducting temperature 8.4 K that closely matches the experiment.