As the traditional silicon-based metal oxide semiconductor field-effect transistors approaching its miniaturization limit, search of alternative ultra-thin channel materials becomes an urgent issue. Silicon can form a two-dimensional single atomic layer, called “Silicene”. It has a graphene-like structure as well as in theoretical calculations both superhigh carrier mobility and controllable energy gap. These make it an ideal ultra- thin channel material. Moreover, with elements same as the present silicon electronic devices, it has a great advantage of zero interfacial contamination when being integrated towards the silicon-bulk leads. It is important to know how to grow silicene on an insulating substrate in the developments of silicene-based devices. In this work we choose the high dielectric material hafnium oxide to be the substrate and perform first-principles calculations at middle and high levels of approximation to crosscheck, where the high level refers to the GW approximation and the middle to the local density approximation, generalized gradient approximation, and hybrid functionals. We choose the hafnium oxide(111) surface to be substrate and look for its particular surface termination atomic layer that can preserve silicene’s superhigh mobility and open up a reasonable bandgap. We expect that this computational study can become the foundation of realizing an on-market transistor with a two-dimensional channel.