English

Multi-scale time-resolved electron diffraction: A case study in moir\'e materials

Instrumentation and Detectors 2023-07-28 v2 Materials Science

Abstract

Ultrafast-optical-pump -- structural-probe measurements, including ultrafast electron and x-ray scattering, provide direct experimental access to the fundamental timescales of atomic motion, and are thus foundational techniques for studying matter out of equilibrium. High-performance detectors are needed in scattering experiments to obtain maximum scientific value from every probe particle. We deploy a hybrid pixel array direct electron detector to perform ultrafast electron diffraction experiments on a WSe2_2/MoSe2_2 2D heterobilayer, resolving the weak features of diffuse scattering and moir\'e superlattice structure without saturating the zero order peak. Enabled by the detector's high frame rate, we show that a chopping technique provides diffraction difference images with signal-to-noise at the shot noise limit. Finally, we demonstrate that a fast detector frame rate coupled with a high repetition rate probe can provide continuous time resolution from femtoseconds to seconds, enabling us to perform a scanning ultrafast electron diffraction experiment that maps thermal transport in WSe2_2/MoSe2_2 and resolves distinct diffusion mechanisms in space and time.

Keywords

Cite

@article{arxiv.2206.08404,
  title  = {Multi-scale time-resolved electron diffraction: A case study in moir\'e materials},
  author = {C. J. R. Duncan and M. Kaemingk and W. H. Li and M. B. Andorf and A. C. Bartnik and A. Galdi and M. Gordon and C. A. Pennington and I. V. Bazarov and H. J. Zeng and F. Liu and D. Luo and A. Sood and A. M. Lindenberg and M. W. Tate and D. A. Muller and J. Thom-Levy and S. M. Gruner and J. M. Maxson},
  journal= {arXiv preprint arXiv:2206.08404},
  year   = {2023}
}

Comments

Submitted manuscript, 22 pages, 5 figures

R2 v1 2026-06-24T11:54:20.233Z