Nowadays, nanowire and 3-D ICs technologies are highly emphasized by many organizations for possible solutions to the current limitations defined by Moore’s Law. Nevertheless, the explorations on their feasibility in transistor level circuitry haven’t been adequately surveyed. In this thesis, we investigate stray capacitance issue and electrical property in the application of circuitry for gate-all-around junctionless nanowire TFTTs (GAA JL-NWTFTs) and 3-D stacked hybrid complementary TFTs (hybrid c-TFTs) separately. For JL-NWTFTTs, according to layout diagram and post-simulation result, the process method to uniformly suspend the nanowire leads to additional parasitic capacitances, resulting in severe degradation of logic performance. For hybrid c-TFTs, comparing the conventional parallel and 3-D stacked structures in several basic logic cells, the area efficiency outperformed the parallel counterparts. However, the worsening logic performance is also explicitly observed. This study reveals the trade-off among device characteristics, area and parasitic issue, which should be considered for the usage of JL-NWTFTs and hybrid c-TFTs in the future 3-D IC and system-on-panel applications.