In this study, the growth mechanism, surface/interface properties, and potential applications of MoS2 are demonstrated. The thickness-dependent surface states of MoS2 thin films grown by the CVD process on the SiO2-Si substrates are investigated by XPS. Both the core levels and valance band edges of MoS2 shift downward ~0.2 eV as the film thickness increases from 3 to 10 layers, which can be ascribed to the variations of Fermi level. Grainy features observed from the AFM topographies, and defect states illustrated at the valance band spectra indicate the influences of both surface states and bulk defects, which lead to the variations of Fermi level in n–type MoS2 with thickness. When Au contacts with our MoS2 thin films, the binding energy reduces due to the hole-doping characteristics of Au, and easy charge transfer from the surface defect sites of MoS2. HER performance also exhibits that the easy charge transfer and the decrease in reaction barrier at the thin MoS2 surface. The anisotropic crystal structure and different properties between edge and basal plane of MoS2 have given rise to versatile applications. Here, we are able to manipulate the orientations of MoS2 by controlling the sulfurization kinetics in both MoO3 and Mo precursors. Thermodynamic information and SEM observations indicate that MoO3 has much higher sulfurization rate than Mo metal in H2S. Introducing H2 with H2S is able to enlarge the rate difference between these two precursors. Raman and XAS studies further reveal the orientation evolution of MoS2 is related to the MoO3/Mo ratio in the precursor, so that MoO3-derived MoS2 is terrace-terminated whereas Mo-derived one is edge-terminated. The differences in the orientation of MoS2 and sulfurization rate between MoO3 and Mo metal are attributed to the crystal structures of the Mo precursors and the reaction routes with H2S. The formation of terrace-terminated MoS2 on the Mo surface is also expected to suppress sulfurization of the bottom Mo metal. The hybrid hexagonal material of 2D-MoS2 and 3D-ZnO is utilized as a memristor. The microstructure of this hybrid material was analyzed by Raman, XRD, and HRTEM. ZnO grown by atomic-layer deposition shows c-axis preferred orientation on terrace-terminated MoS¬2 and stable I-V behavior at the ZnO/MoS2 interface, while edge-terminated MoS2 results in randomly oriented ZnO and unstable I-V characteristics, which could arise from the chemical reaction at the interface. The device with dual-oriented MoS2 on Mo metal is demonstrated by employing both MoO3 and Mo precursors. The MoS2/ZnO interface plays an important role for the resistive switching behaviors. Good retention and endurance of the device is achieved, which could be attributed to the formation of dual-oriented MoS2 on the Mo back contact that offers a stable interface with ZnO. The negative differential resistance (NDR) characteristics and voltage-dependent HRS are observed at the reverse bias, which could be related to the surface properties of MoS2. The shift in binding energy after the formation of MoS2/ZnO n-n+ heterojunction indicates the generation of interface states. Temperature-dependent I-V measurement illustrates that carrier transport mainly follows the trapping/detrapping controlled SCL process accompanying with ionic transportation. The complete switching mechanism is also proposed. This work demonstrates that the combination of oxide with TMD could be a potential configuration for electronic applications.