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Holographic imaging of electromagnetic fields via electron-light quantum interference.

Ivan MadanGiovanni Maria VanacoreEnrico PomaricoG BerrutoR J LambDamien McGroutherTom T A LummenTatiana LatychevskaiaF J García de AbajoFabrizio Carbone
Published in: Science advances (2019)
Holography relies on the interference between a known reference and a signal of interest to reconstruct both the amplitude and the phase of that signal. With electrons, the extension of holography to the ultrafast time domain remains a challenge, although it would yield the highest possible combined spatiotemporal resolution. Here, we show that holograms of local electromagnetic fields can be obtained with combined attosecond/nanometer resolution in an ultrafast transmission electron microscope (UEM). Unlike conventional holography, where signal and reference are spatially separated and then recombined to interfere, our method relies on electromagnetic fields to split an electron wave function in a quantum coherent superposition of different energy states. In the image plane, spatial modulation of the electron energy distribution reflects the phase relation between reference and signal fields. Beyond imaging applications, this approach allows implementing quantum measurements in parallel, providing an efficient and versatile tool for electron quantum optics.
Keyphrases
  • molecular dynamics
  • energy transfer
  • electron transfer
  • solar cells
  • high frequency
  • high resolution
  • single molecule
  • deep learning
  • monte carlo
  • machine learning
  • quality improvement