Atomic Force Microscopy
(AFM) Equipment
Top and side views of
AFM cantilevers and tips mounted on a rectangular substrate, viewed at 45X
magnification.
The cantilever and tip
extend over a window in the AFM scanner to allow optical access.
AFM Images
AFM micrograph of an
interdigitated electrode array composed of 175 nm of Ti that was vapor
deposited (after a photolithograph patterning step) onto a Si wafer. AFM allows highly accurate determination
of the height of such a deposit (as seen in the cross-section below).
This is a
cross-section of the electrode array from a previous image. It is the result of one horizontal scan
of the AFM cantilever across the surface.
This graph allows height information to be easily obtained.
AFM image of a CD
before any data is written. The
raised ridges are used as “tracks” on which a laser writes data
during the “burning” process.
AFM image of a CD after
data is written. Notice the raised
spots on the tracks of the disk.
These spots store the bits of information that are used to transfer
information. AFM is often used to
verify the quality of stamps used for making commercial CDs.
AFM image of a DVD
after data is written. In this
image, it is evident that the storage capacity of a DVD is much greater than
the CD above, as the rows of “tracks” are much closer together.
Single-walled carbon
nanotube (SWNT) network composed of SWNTs deposited on a silicon wafer. Such networks are transparent, flexible
and highly conductive over large areas, making them highly desirable electronic
materials. SWNTs are
nanometer-scale tubes made of graphite, the form of carbon found in pencils
(below).
Three-dimensional
model of an SWNT. Every carbon atom in an SWNT is at its
surface.
Electrical response
of two SWNT-network transistors.
In general, a transistor is composed of a material that has conductivity
that is changed from a high conducting to a low conducting state by application
of a gate voltage. A low density SWNT network behaves
as a transparent, thin-film semiconductor (Left). A high density network behaves as a
metal and shows no response to a gate voltage (Right).
Scanning Tunneling Microscopy
(STM) Images
Large-scale
ultra-high vacuum STM micrograph of a ruthenium (Ru) single crystal surface. The small Ru
islands are a result of the preparation routine used to obtain a clean
surface. Ion sputtering (like
sandblasting with ions) was used to clean the surface. Ru is such a
refractory metal that these small islands don’t coalesce with step edges
even when the metal is heated to 1000º C, as with other metals (see Au
below).
The “soliton” walls (pairs of parallel lines) of the gold
reconstruction are visible in this image.
This reconstruction forms spontaneously on a clean gold surface in air,
liquid and vacuum. These soliton walls are only 0.2 nanometers (or 200 picometers) high, yet STM can
image them easily! Two pits,
surface defects, are also visible.
Large-scale STM image of the surface of a “gold-on-glass”
sample. This was formed by vapor depositing Au
onto a glass slide using a process called thermal evaporation. Each step seen above is a little less
than one atomic layer higher than the next lower (darker) step. On the flat planes, the soliton walls of the Su reconstruction are visible even in
this large scale image.
Large-scale STM image of the surface of a gold singe crystal. The gold reconstruction observed in
previous images has been lifted by immersing this crystal in an electrolyte to
prepare for an electrochemical experiement. The extra atoms that formed the soliton walls now aggregate into small islands on the
surface.
Gold (Au) atoms. Notice how the Au atoms appear lower
than the HOPG atoms two images below. This is because Au is a true metal and
each atom is surrounded by a sea of delocalized electrons. This property makes it more difficult to
image the Au atoms, as they appear to have a low height.
This image was obtained
during the electrodeposition of tellurium on gold. At negative potentials, tellurium atoms
crowd onto the surface to form this pattern.
Atomic resolution
image of highly oriented pyrolytic graphite (HOPG).
Graphite is the same material in pencils, but it also conducts
electricity very well. This is also
the same form of C in carbon nanotubes. In this image,
every other C atom is imaged.
Every atom in HOPG is imaged when the STM tip
is brought closer to the surface and the true hexagonal nature of the graphite
is observed.
Self-assembled
monolayer formed when a solution containing an organic semiconductor is placed
on an HOPG surface. Self-assembly is seen as a potential
route to the mass production of nanomaterials.