In this work, we introduce a double-gated junctionless (JL) field-effect transistor (FET) which contains a hybrid P/N channel proposed by our team previously. The hybrid P/N channel is composed of a p+ channel stacked on an n+ Si layer. The naturally formed depletion layer between the two layers may reduce the effective thickness of the P-type channel. This scheme may not only relieve the constraint imposing on the channel thickness of a JL device, but also reducing the process complexity. Furthermore, the device performance may benefit from the negative bias applied to the back-gate. The above scheme was demonstrated, for the first time, with a polycrystalline silicon-based technology. The fabricated devices show excellent electrical characteristics in terms of steep subthreshold swing (SS = 69 mV/dec), negligible drain-induced barrier lowering (DIBL = 6mV/V), high On-Off current ratio (Ion/Ioff > 108), good threshold voltage (Vth) modulation capability (= 0.08) and reduced low-frequency noise (LFN). Ion increases while Ioff decreases simultaneously as a more negative Vbg is applied. The enhancement of Ion/Ioff ratio is maintained as the temperature is increased from 25℃ to 125℃. The feature makes the scheme potential for low power, System-on-Chip (SoC) and System-on-Panel (SoP) applications. This thesis also demonstrated a JL device with vertically stacked multi-hybrid P/N channels. The fabrication process flow is discussed in detail and the basic electrical characteristics are presented. Specifically, the Ion/Ioff of multi-hybrid P/N channel JL-FET is more than 109. The good device characteristics along with the simple fabrication enable this approach promising for future 3D stacked integrated circuits applications.