High power spark gap switches have a large variety of applications from military science to demolition of buildings. To explore performances and design parameters of spark gap switches, literature of spark gap discharge were surveyed thoroughly. Various mechanisms of gas discharges were reviewed so that conditions and parameters in discharge channels were examined for the guideline of design. An Excel table was established to quick reveal parameters and performance of the designed gap switch. In order to gain a better understanding of scenarios of electric field in the spark gap switches, a set of partial differential equations governing transports of electrons and ions in the gap were numerically solved to simulate time-dependent physical fields. Custom models were coded and linked with COMSOL software package for numerical simulation using an axisymmetric frame. The working gas in the gap is argon at one atmospheric pressure. Detail electric charge intensities and fluxes can provide valuable information to deduce design optimizing of a spark switch. This thesis explores the reaction of spark gap switches under several circumstances and analyzes the dependences of design parameters and pulsed current flux. The parameters involved in analysis include gap distance, the voltage applied to anode and the voltage applied to trigger. The eight simulation cases demonstrated that the conducted pulsed currents could promptly ignite the selected copper foil bridges. It evidences that the current value for each case can meet 4.3X10^3A in the order of ten nano seconds.