In May,
they imaged gold nanoparticles at a resolution of just 97 nanometres, to show that scattering lenses can image below the 200 - nanometre limit of conventional optical lenses (Physical Review Letters, DOI: 10.1103 / PhysRevLett.106.193905).
Not exact matches
a)
Gold nanoparticle catalyst (Au / HAP - NC), b) Images of gold nanoparticles (black dot in red circle) through Transmission Electron Microscope, c) Annular Dark Field of gold nanoparticles through Scanning Electron Microsc
Gold nanoparticle catalyst (Au / HAP - NC), b)
Images of
gold nanoparticles (black dot in red circle) through Transmission Electron Microscope, c) Annular Dark Field of gold nanoparticles through Scanning Electron Microsc
gold nanoparticles (black dot in red circle) through Transmission Electron Microscope, c) Annular Dark Field of
gold nanoparticles through Scanning Electron Microsc
gold nanoparticles through Scanning Electron Microscope.
Electron microscope
images of visible - NIR light responsible photocatalyst composed with black phosphorous (BP), lanthanum titanate (LA2Ti2O7, LTO), and
gold nanoparticles (Au).
The electron microscope
images, or micrographs, showed complex crystalline structures that formed in large part thanks to the shape of the
gold nanoparticles.
This electron microscope
image shows a dimer of silver plated
gold nanoparticles.
An international team working at the Department of Energy's Lawrence Berkeley National Laboratory (Berkeley Lab) has captured the first high - resolution 3 - D
images from individual double - helix DNA segments attached at either end to
gold nanoparticles.