Cerenkov radiation in vacuum from a superluminal grating

Abstract

Nothing can physically travel faster than light in vacuum. This is why it has been considered that there is no Cerenkov radiation (CR) without an effective refractive index due to some background field. In this Letter, we theoretically predict CR in vacuum from a spatiotemporally modulated boundary. We consider the modulation of traveling wave type and apply a uniform electrostatic field on the boundary to generate electric dipoles. Since the induced dipoles stick to the interface, they travel at the modulation speed. When the grating travels faster than light, it emits CR. In order to quantitatively examine this argument, we need to calculate the field scattered at the boundary. We utilise a dynamical differential method, which we developed in the previous paper, to quantitatively evaluate the field distribution in such a situation. We can confirm that all scattered fields are evanescent if the modulation speed is slower than light while some become propagating if the modulation is faster than light.