Add to ORKGUsing a highly coherent focused electron probe in a 5th order aberration-corrected transmission electron microscope, we report on resolving a crystal spacing less than 50 pm. Based on the geometrical source size and residual coherent and incoherent axial lens aberrations, an electron probe is calculated, which is theoretically capable of resolving an ideal 47 pm spacing with 29percent contrast. Our experimental data show the 47 pm spacing of a Ge 114 crystal imaged with 11-18percent contrast at a 60-95percent confidence level, providing the first direct evidence for sub 50-pm resolution in ADF STEM imaging
Abstract: The ability of electron microscopes to analyze all the atoms in individual nanostructures ...
© 2017 Dr. Hamish Galloway BrownScanning transmission electron microscopy (STEM) is capable of imagi...
Aberration correction has brought about a revolution in electron microscopy, with as much progress b...
Using a highly coherent focused electron probe in a 5th order aberration-corrected transmission elec...
Using a highly coherent focused electron probe in a 5th order aberration-corrected transmission elec...
Phase-contrast imaging in the high-resolution electron microscope produces images with peaks at atom...
In the scanning transmission electron microscope (STEM), the spatial resolution of experimental imag...
ORNL/CP-100163 Annular dark-field (ADF) imaging in a scanning transmission electron microscope (STEM...
Phase-contrast imaging in the high-resolution electron micrscope produces images with peaks at atom...
Transmission electron microscopy is an extremely powerful technique for direct characterization of l...
We evaluate the probe forming capability of a JEOL 2200FS transmission electron microscope equipped ...
Despite the use of electrons with wavelengths of just a few picometers, spatial resolution in a tran...
Despite the use of electrons with wavelengths of just a few picometers, spatial resolution in a tran...
Twenty-five years ago, the Cowley group at ASU pioneered the use of transmission electron microscopy...
John Cowley and his group at Arizona State University pioneered the use of transmission electron mi...
Abstract: The ability of electron microscopes to analyze all the atoms in individual nanostructures ...
© 2017 Dr. Hamish Galloway BrownScanning transmission electron microscopy (STEM) is capable of imagi...
Aberration correction has brought about a revolution in electron microscopy, with as much progress b...
Using a highly coherent focused electron probe in a 5th order aberration-corrected transmission elec...
Using a highly coherent focused electron probe in a 5th order aberration-corrected transmission elec...
Phase-contrast imaging in the high-resolution electron microscope produces images with peaks at atom...
In the scanning transmission electron microscope (STEM), the spatial resolution of experimental imag...
ORNL/CP-100163 Annular dark-field (ADF) imaging in a scanning transmission electron microscope (STEM...
Phase-contrast imaging in the high-resolution electron micrscope produces images with peaks at atom...
Transmission electron microscopy is an extremely powerful technique for direct characterization of l...
We evaluate the probe forming capability of a JEOL 2200FS transmission electron microscope equipped ...
Despite the use of electrons with wavelengths of just a few picometers, spatial resolution in a tran...
Despite the use of electrons with wavelengths of just a few picometers, spatial resolution in a tran...
Twenty-five years ago, the Cowley group at ASU pioneered the use of transmission electron microscopy...
John Cowley and his group at Arizona State University pioneered the use of transmission electron mi...
Abstract: The ability of electron microscopes to analyze all the atoms in individual nanostructures ...
© 2017 Dr. Hamish Galloway BrownScanning transmission electron microscopy (STEM) is capable of imagi...
Aberration correction has brought about a revolution in electron microscopy, with as much progress b...