Ultrafast Transverse Modulation of Free Electrons by Interaction with Shaped Optical Fields

Spatio-temporal shaping of electron beams is a bold frontier in electron microscopy, enabling new routes toward spatial-resolution enhancement, selective probing, low-dose imaging and faster data acquisition. Over the last decade, shaping methods evolved from passive phase plates to low-speed electrostatic and magnetostatic displays. Recently, higher shaping speed and flexibility have become feasible by the advent of ultrafast electron microscopy, embodying a swift change of paradigm that relies on using light to control free electrons. Here, we experimentally demonstrate that arbitrary transverse modulation of electron beams is possible without the need for designing and fabricating complicated electron-optics elements or material nanostructures, but rather resorting to shaping light beams reflected from a planar thin film. We demonstrate arbitrary transverse modulation of electron wavepackets via inelastic interaction with a shaped ultrafast light field controlled by an external spatial light modulator (SLM). We illustrate this method by generating Hermite-Gaussian (HG) electron beams with HG10 and HG01 symmetry and discuss their possible use in enhancing the imaging contrast of microscopic features. Relative to current schemes, our approach adopting an external SLM dramatically widens the range of patterns that can be imprinted on the electron wave function and makes electron shaping a much easier task to perform.