Wergin and Erbe have used their low -
temperature scanning electron microscope to infer what happens when falling ice crystals run into fogs of supercooled water droplets on their way down, a common occurrence.
Then in December 1993, he and Eric Erbe, a colleague at the U.S. Department of Agriculture's Electron Microscopy Unit in Beltsville, Maryland, started experimenting with a newly configured low -
temperature scanning electron microscope.
Not exact matches
The researchers used an ultrastable, variable -
temperature stage in an aberration - corrected
scanning transmission
electron microscope to subject an array of size - selected gold nanoparticles (or clusters) to
temperatures as high as 500 °C while imaging them with atomic resolution.
The image, captured by a
scanning electron microscope, was taken as the nanowires grew on silicon at room
temperature.
However, researchers were able to both culture samples from the medical equipment and see it on the surface of
temperature probes using a
scanning electron microscope.
Klie and his colleagues heated microscopic «flakes» of various TMDs inside the chamber of a
scanning transmission
electron microscope to different
temperatures and then aimed the
microscope's
electron beam at the material.
The research, a 3 - way collaboration between Birmingham, Swansea and Genoa, used an ultrastable, variable -
temperature stage in an aberration - corrected
scanning transmission
electron microscope to subject an array of size - selected Au nanoparticles (or clusters) to
temperatures as high as 500 °C while imaging them with atomic resolution.