The main object of this study is focused on the fabrication of the electron emitting device called Surface Conduction Electron Emission Devices (SCE Devices). The most critical process to fabricate the SCE device is how to produce gaps in nanometer scale with a low turn-on voltage and great field emission characteristics. We present two kinds of fabrication method to form the nanogap on palladium cathode as electron emitting source. First one is focused ion beam (FIB) sputter etching system, by using various beam energy and location, we can define nanogaps of different width and location. The turn-on voltage decreased with decreasing of the nanogap width, and different gap lacation will arise different field emission results. Oxidized palladium cathode with high temperature annealing in low pressure oxygen atmosphere cause the formation of palladium oxide. It will change the gap width and the roughness of the emitting source and bring about better field emission characteristics. The other method is hydrogenation, it is based on that a large stress develops in the metal due to phase transformation leading to volume expansion. The width of nanogap could be controlled by adjusting the hydrogen pressure and the Pd film temperature. The deposition rate of palladium film will affect the formation of gap. By comparing palladium film with different deposion rate,we find out that the film with lower deposition rate will have better property to form nanogap.