• NaibofTabr@infosec.pub
    link
    fedilink
    English
    arrow-up
    0
    ·
    edit-2
    6 months ago

    The brighter spots are the nuclei of the Pr, Sc, and O atoms, which are reflecting the electrons of the scanning beams (because they’re comparatively much heavier).

    The space in between the nuclei is where the electrons from all of the atoms are. Because the atoms are bound as PrScO3, the electrons are shared and not really part of any one particular atom or other.

    Technically all of it is “the atoms” because the electrons are part of the structure as much as the protons and neutrons.

    This diagram in the article is helpful:

    The drawing in the lower right shows how the atoms are arranged. The double spots are the nuclei of two Pr atoms very close together. The slightly fainter, elongated spots are actually ScO2 that is arranged as O-Sc-O. The fainter single spots are the other O nuclei that fill out the PrScO3 structure.

    • plandeka@lemmy.world
      link
      fedilink
      English
      arrow-up
      0
      ·
      edit-2
      6 months ago

      That is only sort of true - this image is not made of electrons reflected by the nuclei. These are results from TEM imaging, so Transmission Electron Microscopy. The electron detector is placed behind the sample.

      What you are describing is SEM - Scanning Electron Microscopy - in that case, the detector can be placed above the sample, for example (but not limited to) circularly around the beam to measure the backscattered electrons

      In TEM the samples are cut into very thin slices (in the picture you posted it is said to be between 0.8nm - 30nm) and the crystal lattice acts as a diffraction grating for the electron beam. The diffraction pattern can be then used to reconstruct the crystal lattice structure.