From photographs of movement that's too fast for the human eye to perceive, to
atomic force microscope images of atomic bonds, pictures created by new technologies have often catalyzed scientific discovery.
Not exact matches
This artist rendering is based on an
image of deoxyribonucleic acid (DNA) taken with an
atomic force microscope (AFM).
The tips (see
image below) are comparable to the probes of an
atomic force microscope and can be moved across magnetic elements of inorganic or biological materials with high precision.
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.
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 bonds.
The challenge was to collect
images based on data gathered by NT - MDT's
atomic force microscope (AFM) probes.
Atomic force microscopes are able to reproduce spectacular
images, at the scale of single atoms.
Methods: In their work, El - Khoury and his colleagues employed a gold tip of an
atomic force microscope to record chemical
images (25 nm spatial resolution) of a silver surface coated with 4,4» - dimercaptostilbene.
The
image was created with an
atomic force microscope and a process called ThermoChemical NanoLithography (TCNL).
A French and Japanese research group has developed a new way of visualizing the
atomic world by turning data scanned by an
atomic force microscope into clear color
images.
An
atomic force microscope (AFM) is a scientific tool that is used to create detailed three - dimensional
images of the surfaces of materials, down to the nanometer scale — that's roughly on the scale of individual molecules.
«Bringing the
atomic world into full color: Researchers turn
atomic force microscope measurements into color
images.»
It is versatile because an
atomic force microscope can not only
image in three - dimensional topography, but it also provides various types of surface measurements to the needs of scientists and engineers.
Almost as clearly as a textbook diagram, this
image made by a noncontact
atomic force microscope reveals the positions of individual atoms and bonds, in a molecule having 26 carbon atoms and 14 hydrogen atoms structured as three connected benzene rings.
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.
Now engineers at MIT have designed an
atomic force microscope that scans
images 2,000 times faster than existing commercial models.
This
image was produced by an
atomic force microscope.
IMAGE: Using the
atomic force microscope's carbon monoxide functionalized tip (red / silver), the
forces between the tip and the various atoms in the graphene ribbon can be measured.