Researchers claim this scanning electron
microscope image captures collagen fibrous material from an 80 - million - year - old dinosaur fossil.
On the left, a scanning tunneling
microscope image captures the bright shape of the moly sulfide nanocluster on a graphite surface.
Not exact matches
Using a
microscope, researchers can
image the
captured atoms in real time, and then arrange them into arbitrary patterns to make up the system's input.
FlatScope is being developed at Rice University for use as a fluorescent
microscope able to
capture three - dimensional data and produce
images from anywhere within the field of view.
This
image,
captured with an epifluorescence
microscope, shows neural pathways known as «fiber tracts» that are trapped on hexagonal microstructures made of silicon.
High - resolution transmission
microscope (left) and scanning electron
microscope images of a porous carbon sample studied for its ability to
capture carbon dioxide from natural gas.
The
image,
captured by a scanning electron
microscope, was taken as the nanowires grew on silicon at room temperature.
The following
images capture the beauty of a world measured in atoms rather than inches, made visible with specialized
microscopes and fabrication techniques and all made possible with NSF funding.
After working on the problem for years, in 1990, Henderson
captured the first 3 - D
image of a protein using an electron
microscope.
Amat, a bioinformatics specialist on Keller's team, and his colleagues have solved that problem with the new computational method that identifies and tracks dividing cells as quickly as their high - speed
microscope can
capture images.
Instead of approaching the problem by creating better imaging software that helps to increase the resolution after the fact, as most high resolution
microscopes do, Shroff and his lab developed a
microscope with better lenses and mirrors so that the higher resolution is
captured in the original
image.
This perpendicular view results in undistorted 3 - dimensional
images, and since only two views are acquired, the
microscope can still
capture events at very high speed.
In this
image,
captured by an electron
microscope, HIV is infecting these CD4 T immune cells.
Adapters are available to attach a smartphone to a slit lamp — a
microscope with an adjustable, high - intensity light — to
capture images of the front of the eye.
Researchers at the University of Leeds and in Japan used electron
microscopes to
capture images of the largest type of motor protein, called dynein, during the act of stepping along its molecular track.
The
microscope captures 3D
images about once per second at resolutions of about 200 to 250 nanometers, not atomic resolution, but still at a dynamic level never before seen.
Imaging was done by Olympus BX 61 Fluorescent
microscope and
images were
captured by
Image Pro Express software.
Lenses are used in
microscopes and cameras to focus light, thus allowing a researcher to see small things or a photographer to
capture image of things that are far away.
Images of Spheroids were
captured by Olympus CKX41 inverted
microscope.
It has been previously demonstrated that a camera - enabled mobile phone can be used to
capture images from the eyepiece of a standard
microscope [11] and that microscopy
images can be wirelessly transmitted for subsequent analysis [12].
State - of - the - art atomic force
microscopes (AFMs) are designed to
capture images of structures as small as a fraction of a nanometer — a million times smaller than the width of a human hair.
Images were
captured by a Zeiss digital camera connected to a Zeiss VivaTome
microscope (Carl Zeiss Microscopy, LLC, Thornwood, NY, USA), and
image analysis on sections was performed using Axiovision software (Carl Zeiss Microscopy, LLC, Thornwood, NY, USA).
All
images were
captured using a confocol
microscope (Leica).
Researchers used a powerful X-ray
microscope at Berkeley Lab's Advanced Light Source (ALS) to
capture images of nerve cell samples at different stages of maturity as they became more specialized in their function — this process is known as «differentiation.»
Thanks to some remarkable developments in
microscopes and staining tools, we can easily
capture images and sit in awe and wonder at the hitherto invisible beauty found in nature.
Bright field
images were
captured using a Leica DM 5000B compound
microscope with a DFC320 camera and the Leica
image capture suite software.
An eyepiece camera that attaches to a binocular
microscope usually requires replacing one of the
microscope eyepieces with the eyepiece camera to
capture images directly on a computer (FIGURE 2).
At ASU's Center for Meteorite Studies, they have harvested new
images from thinly sliced sections of the meteorite under a petrographic
microscope, exploring and
capturing the stunningly brilliant and mysterious silicate inclusions.