In this thesis, a novel device featuring a side-gate and suspended nanowire (NW) channels is proposed and demonstrated. The nanwire channels are formed with sidewall spacer etching technique, and become suspended by stripping the sacrificial oxide layer between the gate nitride and nanowire channels. The presence of air gap leads to a movable channel controlled by the gate bias. Despite a much larger equivalent oxide thickness due to the air gap, the suspended nanowire channel devices depict a better subthreshold swing over the devices without stripping the sacrificial oxide (i.e., no air gap). Moreover, an interesting oscillation phenomenon of suspended nanowire during the device operation is observed. The hysteresis phenomenon in the subthreshold characteristics due to the motion of the suspended nanowire is reported, for the first time, in this thesis. Nevertheless, most of the suspended nanowire devices do not show an abrupt turn-on behavior (i.e., with S.S. < 60mV/dec). A model considering the gradual contact of NW channel with the gate nitride is proposed to explain the operation principles of the fabricated devices.