Electrophoretic motion of a charged liquid droplet or a bubble normal to an air-water interface is investigated theoretically in this study, motivated by the rapid development of various practical applications involving micro/nano emulsions, as well as the fascinating potentials of using the air-water interface as a platform for the two-dimensional colloidal crystallization, for instance. The presence of an air-water interface is found to reduce the droplet/bubble mobility in general, especially when the double layer is thick or the particle is close to the interface. Special attention is given to the boundary effect upon the convection-induced motion-deterring double layer polarization effect pertinent to highly charged colloids. As demonstrated by various contour plots of both electric and flow fields, the presence of an air-water interface affects the particle motion mainly through the deformation of the double layer when it touches the interface. A counterclockwise vortex flow around the droplet/bubble is observed which pumps up the counterions originally in the wake to the front region. This significantly alleviates the motion-deterring polarization effect when the thickness of double layer is comparable to the droplet/bubble radius. The release of this brake (polarization effect) refuels the electric driving force of the droplet/bubble hence affects its motion near the interface as observed. Convenient charts of correction factors for the boundary effect, expressed as a function of separation distance, are provided to facilitate the possible usage by interested researchers and engineers.