A transmission electron
microscope image taken at Argonne shows the honeycomb structure of the silicon nanowires.
Not exact matches
The only species Onstott has observed in action are nematode worms; he could see them squirming under a
microscope, and
took detailed electron microscopy
images of their hundredth - of - an - inch - long bodies.
«One rather exciting feature is that the
images taken under the electron
microscope show the nanowires to have a slightly different shape,» says co-author Thomas Keller from DESY NanoLab.
Image of a blood smear from a cell phone camera (left), following enhancement by the algorithm (center), and
taken by a lab
microscope (right).
The Shot: Pan
took this digital
image with an Olympus FluoView FV1000 confocal
microscope using a 20x objective and a photomultiplier tube.
This artist rendering is based on an
image of deoxyribonucleic acid (DNA)
taken with an atomic force
microscope (AFM).
The
image, captured by a scanning electron
microscope, was
taken as the nanowires grew on silicon at room temperature.
The neurons were traced from a large set of monochrome pictures of the rabbit's retina
taken with an electron
microscope, such as the black - and - white
images on either side of the neural tangle.
These scanning electron
microscope images of coccolithophorids were all
taken by Markus Geisen of the Alfred Wegener Institute for Polar and Marine Research in Bremerhaven, Germany.
This an
image taken of a toroid using a confocal
microscope, false - colored by height.
The identification is based on
images taken with a scanning electron
microscope.
Both
images are
taken with a scanning electron
microscope.
The emitted light is blue - green, Lupton says, but
images accompanying the paper —
taken with a scanning tunneling electron
microscope — show the rotelle - and spaghetti - shaped molecules with a false yellow - brown color to provide good contrast.
The
image has been
taken in a fluorescence
microscope.
Now they will be able to see the
images instantly instead of waiting hours or sometimes days, and the data itself
takes about 1 % of the hard drive space as that produced by previous
microscopes.
Traditionally, SPIM
microscopes rotate the sample so that they can clearly see all the dimensions, but this severely limits the imaging speed and can increase the damage done to the cells from light exposure because of the many extra
images taken at multiple angles.
Using electron
microscopes, the scientists
took images of the thin films (about 100 nanometers thick) of the material they prepared, before and after they hit the films with low - energy protons.
Image taken with polychromatic scanning electron
microscope.
Images taken with an electron
microscope confirmed that not only was its DNA separate from the rest of the cell, it was enclosed by a double membrane — just like the membrane envelope surrounding the nucleus of complex cells.
The researchers developed a novel algorithm that can recover the phase information from a stack of bright - field
images taken by a classical
microscope.
Unlike many
images of crystalline structures, this one is not
taken with an electron
microscope.
Images taken with a fluorescent
microscope show the activity of a kinase (green) in tumor cells (bottom) compared to normal cells (top).
An automated
microscope takes images every 20 minutes at multiple locations in the microfluidic device, and multiple devices at once, allowing for the tracking of dozens of cells in one experiment.
A software - controlled
microscope peers into each capillary and
takes images of the biochemical reaction occurring therein.
Now Peter Velikov and Siu - Tung Yau at the University of Alabama at Huntsville have used an atomic force
microscope to
take the first
images of the birth of the seed crystals, a process called nucleation.
First
image of the structure of a silicon crystal lattice
taken by scanning tunneling
microscope (STM), by Gerd Binnig and Heinrich Rohrer (1983) STM is one of the primary methods we use to see individual atoms and molecules, and it revolutionized many areas of science, including materials science (nanotechnology).
The molecular bonds in a Pentacene molecule, by IBM Research (2009)
Taken with an atomic force microscope, which grew out of the technologies pioneered by Bennig and Rohrer's STM, this is the first image ever taken that shows molecular b
Taken with an atomic force
microscope, which grew out of the technologies pioneered by Bennig and Rohrer's STM, this is the first
image ever
taken that shows molecular b
taken that shows molecular bonds.
The results, and some incredible
images taken by electron
microscope, were published in Science on Sunday night.
Images were
taken with the confocal
microscopes Zeiss LSM710 and
image analysis was accomplished with Fiji (ImageJ).
The
image was
taken with a confocal laser scanning
microscope and shows cells giving strong inmmunofluorescence staining for CD3 antigen (green), indicating presence of cells of T - lymphocytes origin in the infarct zone of the heart tissue, counterstained nuclei with DAPI (blue).
Images were
taken on a Zeiss LSM 510 confocal
microscope (Carl Zeiss, Canada) equipped with Argon and Helium - Neon lasers.
Images of lungs were
taken using a digital
microscope camera.
By
taking multiple
images of the iron - platinum nanoparticle with an advanced electron
microscope at Lawrence Berkeley National Laboratory and using powerful reconstruction algorithms developed at UCLA, the researchers determined the precise three - dimensional arrangement of atoms in the nanoparticle.
Nodules on the surface of lungs were visualized under the dissecting
microscope, and a USB digital camera (Leica Microsystems, Bannockburn, IL, USA) from the
microscope was used to
take gross
images of each lung.
Images were
taken on a DeltaVision OMX V4 Blaze super-resolution
microscope (Applied Precision, GE Healthcare).
The
image was
taken using a fluorescent
microscope at the SLIM facility in the School of Life Sciences.
Ban's group — which developed the coating for silicon electrodes, called alucone, and is currently the only group that can create alucone - coated silicon particles —
took high magnification
images of the particles in an electron
microscope.
An
image taken with a
microscope shows a cross section of the trap of a humped bladderwort (Utricularia gibba).
This is your last opportunity to view this ground breaking exhibition, featuring 15 larger - than - life
images taken with a scanning electron
microscope.