In this thesis, the electron transport properties and the fabrication of Josephson junction in a hybrid high-temperature superconductor and graphene were investigated. The idea of adopting high-temperature superconductor, EuBaCuO (EBCO), and graphene derived from the Andreev reflection and proximity effect observed between the interface of the low-temperature superconductor and graphene; attempting to have a comprehensive picture of the aforementioned effects and the fundamental properties of the superconducting carriers in the Josephson junction in a variety of superconductors. Besides what we mentioned in the previous paragraph, the rest of this thesis was dedicated to the study of the electrons transport properties in the epitaxial graphene. The behaviors of the insulator-quantum Hall transition and weak localization in the epitaxial graphene were observed in this study. Moreover, our experimental results suggested that the electron heating effect is a powerful tool for studying two scattering properties which are difficult to study independently and physical phenomena in two-dimensional systems or nanostructures. Finally, we successfully demonstrated the fabrication of high-temperature superconducting/graphene Josephson junction and evidences responsible for Andreev reflection phenomenon observed in the high-temperature superconductors/graphene Josephson junction. The results of this unprecedented materials combination shed a light on the future development of its cutting-edge applications.