Attomicroscopy: from femtosecond to attosecond electron microscopy

Hassan, M. Th.

doi:10.1088/1361-6455/aaa183

Cited by 39 publications

(25 citation statements)

References 179 publications

(372 reference statements)

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“…Currently, with the aid of subfemtosecond (fs, 10 −15 s) lasers 3,4 and highly coherent electron sources, 5,6 it is possible to simultaneously achieve attosecond (as, 10 −18 s) temporal resolution and subnanometer (nm, 10 −9 m) spatial resolution. 7,8 Ultrafast imaging holds great promise for advancing science and technology, and it has already been widely used in both scientific research and industrial applications.…”

Section: Introductionmentioning

confidence: 99%

Single-shot compressed ultrafast photography: a review

Zhang

Yang

et al. 2020

Adv. Photon.

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Compressed ultrafast photography (CUP) is a burgeoning single-shot computational imaging technique that provides an imaging speed as high as 10 trillion frames per second and a sequence depth of up to a few hundred frames. This technique synergizes compressed sensing and the streak camera technique to capture nonrepeatable ultrafast transient events with a single shot. With recent unprecedented technical developments and extensions of this methodology, it has been widely used in ultrafast optical imaging and metrology, ultrafast electron diffraction and microscopy, and information security protection. We review the basic principles of CUP, its recent advances in data acquisition and image reconstruction, its fusions with other modalities, and its unique applications in multiple research fields.

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Section: Introductionmentioning

confidence: 99%

Single-shot compressed ultrafast photography: a review

Zhang

Yang

et al. 2020

Adv. Photon.

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“…The HBT effect for photons [4] was pivotal in the development of the field of quantum optics, and the observation of the same effect for free electron beams may open up a new field of research. Additionally, ever more dense electron pulses are being produced for Ultrafast Electron Diffraction (UED), Ultrafast Electron Microscopy (UEM), and laser wake field acceleration, where single shot electron diffraction imaging of single molecules is one of the major outstanding challenges [5][6][7]. The question on what limits the density of single electron pulses, degeneracy pressure or Coulomb interaction, is both relevant for quantum mechanics and for applications, such as making molecular movies.…”

Section: Introductionmentioning

confidence: 99%

Partially coherent quantum degenerate electron matter waves

Keramati

Jones

Armstrong

et al. 2020

Advances in Imaging and Electron Physics

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The use of electron beams is ubiquitous; electron microscopy, scanning tunneling microscopy, electron lithography, and electron diffractometry all use well-collimated and focused beams. On the other hand, quantum degenerate electron beams do currently not exist. The realization of such beams may impact all electron beam technologies and are interesting to pursue. Past attempts to reach degeneracy were hampered by the low degeneracy of continuously emitting electron sources. With the recent advent of ultra-short electron pulses, high degeneracy is expected. Coulomb repulsion and low quantum coherence are hurdles that need to be overcome. A quantum analysis of the electron degeneracy for partially coherent pulsed electron sources is presented and two-particle coincidence spectra are obtained for source parameters that are currently available. The conclusive demonstration of the fermionic Hanbury Brown-Twiss (HBT) effect for free electrons is shown to be within reach, and our results support the claim that femto-second nanotip electron sources, both polarized and unpolarized, can manifest partial to complete quantum degeneracy with appreciable signal-to-noise-ratios for free electron pulses notwithstanding their small particle numbers.

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“…To generate high-brightness electron beams with pulse durations on the order of 100 fs, an advanced accelerator technology for radio-frequency (RF) acceleration-based photoemission electron guns (photocathode RF guns) has been proposed to generate multi-MeV femtosecond electron pulses for UED [16][17][18][19][20][21][22][23][24][25][26][27]. The RF gun is usually operated with a high RF electric field equal to or >100 MV/m.…”

Section: Introductionmentioning

confidence: 99%

Femtosecond Electron Diffraction Using Relativistic Electron Pulses

Yang¹

2020

Novel Imaging and Spectroscopy

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Observation of atomic-scale structural motion in matter with femtosecond temporal resolution is of considerable interest to scientists and paves the way for new science and applications. For this purpose, ultrafast electron diffraction (UED) imaging using femtosecond electron pulses is a very promising technique, as electrons have a larger elastic scattering cross section as compared to photons or X-rays and can be easily focused in observation with high spatial resolution. In this chapter, we first give an overview of the historical development of current nonrelativistic UEDs and discuss the potentials of UEDs with relativistic electron pulses. Second, we describe the concept and development of relativistic UED with femtosecond electron pulses generated by a radio-frequency acceleration-based photoemission gun. Some demonstrations of diffraction imaging of crystalline materials using 3-MeV electron pulses with durations of $100 fs are presented. Finally, we report a methodology of single-shot time-resolved diffraction imaging for the study of ultrafast dynamics of photo-induced irreversible phase transitions.

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Attomicroscopy: from femtosecond to attosecond electron microscopy

Cited by 39 publications

References 179 publications

Single-shot compressed ultrafast photography: a review

Single-shot compressed ultrafast photography: a review

Partially coherent quantum degenerate electron matter waves

Femtosecond Electron Diffraction Using Relativistic Electron Pulses

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