Among two-dimensional transition-metal dichalcogenides (TMDCs), MoS2 is attracting significant attention as a key channel material for next-generation electronic devices due to its atomic-scale thickness and unique semiconducting properties. The electrical characteristics of field-effect transistors (FETs) are determined by the interface properties between the channel material and the gate dielectric, enabling performance control through interface engineering. In this study, we fabricated back-gate MoS2 FETs and systematically analyzed the impact on device performance by replacing the conventional SiO2 gate dielectric with a high-k material, HfO2. The devices were fabricated by depositing the HfO2 dielectric via atomic layer deposition (ALD) and forming the MoS2 channel using a mechanical exfoliation and dry transfer process. The result revealed that HfO2-based FETs exhibited and a threefold enhancement in field-effect mobility and an ~81% reduction in subthreshold swing relative to devices employing conventional SiO2 dielectrics. These findings suggest that MoS2 FETs incorporating an HfO2 dielectric are promising for the development of next-generation low-power, high-performance semiconductor devices.