The realization of superconducting circuits and the investigation of the critical quantum phase transition are two backbones of contemporary experimental research in condensed matter physics. We chose one topic from each of these two disciplines to study in this thesis: one is contributed to the electrical and magneto-transport properties of Josephson junctions, and the other focuses on the discussion of insulator-quantum Hall (I-QH) transition in monolayer epitaxial graphene. Firstly, we observe possibly the multiple Andreev reflection (MAR) in the vertical Al/AlOx/Al Josephson junction mainly fabricated by the molecular beam epitaxy (MBE). Although the materials used to construct the superconducting electrodes and the tunneling barrier are not novel, the complexity of the fabrication of the Josephson junction is considerably reduced. The deposition of the Al superconducting electrodes and the formation of the AlOx oxide layer are all completed in the MBE system, and the photolithography only needs to be performed with respect to one of the superconducting electrodes. In the current-voltage characteristics obtained from the standard four-terminal measurement, two-stage transition behaviors and MAR are perceived. However, the dependence of the critical current on the temperature and magnetic field does not show great agreement with the typical behaviors of tunneling junction, which are attributed to the appreciable contribution of the non-Josephson barrier shorts. This result demonstrates the development of the simpler fabrication process for the Al/AlOx/Al Josephson junction in this work needs to be modified, especially on the large-area overlap of the bonding pad and the AlOx oxide layer. Secondly, we detected a transition from an insulating state (ν=0), in which ρ_xx decreases with increasing temperature, to a high Landau-level-filling-factor >2 (ν=6) QH state in monolayer epitaxial graphene grown on SiC with additional multilayer Cr(CO)3 capping on the graphene. This transition is the so-called direct I-QH transition, which is characterized by an approximately temperature-independent point in the measured longitudinal resistivity ρ_xx at a critical magnetic field, B_c. Through the standard scaling analysis for the direct I-QH transition, the critical exponent κ is determined to be 0.15, which is close to the value of κextracted from the ν=6 to ν=2 plateau-plateau transition, 0.14, in the literature. With this finding, we suggest that these two phase transitions may belong to the same universality.