The Korea Advanced Institute of Science and
Technology (KAIST) announced that a research team from the Department of
Materials Science and Engineering has developed a technology that enables
scientists and engineers to observe processes occurring in liquid media on the
smallest possible scale which is less than a nanometer.
Professor
Jeong Yong Lee and Researcher Jong Min Yuk, in collaboration with Professor
Paul Alivisatos's and Professor Alex Zettl's groups at the University of
California, Berkeley, succeeded in making a graphene liquid cell or capsule,
confining an ultra-thin liquid film between layers of graphene, for real-time
and in situ imagining of nanoscale processes in fluids with atomic-level
resolution by a transmission electron microscope (TEM). Their research was
published in the April 6, 2012 issue of Science.
The graphene
liquid cell (GLC) is composed of two sheets of graphene sandwiched to create a
sealed chamber where a platinum growth solution is encapsulated in the form of
a thin slice. Each graphene layer has a thickness of one carbon atom, the
thinnest membrane that has ever been used to fabricate a liquid cell required
for TEM.
The
research team peered inside the GLC to observe the growth and dynamics of
platinum nanocrystals in solution as they coalesced into a larger size, during
which the graphene membrane with the encapsulated liquid remained intact. The
researchers from KAIST and the UC Berkeley identified important features in the
ongoing process of the nanocrystals' coalescence and their expansion through
coalescence to form certain shapes by imaging the phenomena with atomic-level
resolution.
Professor
Lee said, "It has now become possible for scientists to observe what is
happening in liquids on an atomic level under transmission electron
microscopes."
Researcher
Yuk, one of the first authors of the paper, explained his research work.
"This
research will promote other fields of study related to materials in a fluid
stage including physical, chemical, and biological phenomena at the atomic
level and promises numerous applications in the future. Pending further studies
on liquid microscopy, the full application of a graphene-liquid-cell (GLC) TEM
to biological samples is yet to be confirmed. Nonetheless, the GLC is the most
effective technique developed today to sustain the natural state of fluid
samples or species suspended in the liquid for a TEM imaging."
The
transmission electron microscope (TEM), first introduced in the 1930s, produces
images at a significantly higher resolution than light microscopes, allowing
users to examine the smallest level of physical, chemical, and biological
phenomena. Observations by TEM with atomic resolution, however, have been
limited to solid and/or frozen samples, and thus it has previously been
impossible to study the real time fluid dynamics of liquid phases.
TEM
imaging is performed in a high vacuum chamber in which a thin slice of the
imaged sample is situated, and an electron beam passes through the slice to
create an image. In this process, a liquid medium, unlike solid or frozen
samples, evaporates, making it difficult to observe under TEM.
Attempts
to produce a liquid capsule have thus far been made with electron-transparent
membranes of such materials as silicon nitride or silicon oxide; such liquid
capsules are relatively thick (tens to one hundred nanometers), however,
resulting in poor electron transmittance with a reduced resolution of only a
few nanometers. Silicon nitride is 25 nanometers thick, whereas graphene is
only 0.34 nanometers.
Graphene,
most commonly found in bulk graphite, is the thinnest material made out of
carbon atoms.
It has
unique properties such as mechanical tensile strength, high flexibility,
impermeability to small molecules, and high electrical conductivity. Graphene
is an excellent material to hold micro- and nanoscopic objects for observation
in a transmission electron microscope by minimizing scattering of the electron
beam that irradiates a liquid sample while reducing charging and heating
effects.
ScienceDaily
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