Unbelievably they produce usable
forms of graphene from graphite. I
suspect this will at least make the miners slightly optimistic. What is indicated here is that bulk graphene
can be produced and formed up into a wide range of geometries in order to utilize
there capabilities. It is time to let
you imagination run wild again. Perhaps
a manufactured laminar layer consisting of a continuous upper and lower layer
containing a sandwich of graphene pieces nicely bound and even self
healing. I would love to wear that as
armor.
My point is that this describes a
materials revolution that will change everything as it gets very cheap. The raw material is amply available. It describes an industrialisable process.
Now imagine that shell being
formed to produce automobiles that effectively absorb the total shock of a
crash by ballooning out and actually springing back.
This is just the beginning but
this will be wild.
Simple, cheap way to mass-produce graphene nanosheets
RESEARCHERS IN SOUTH
KOREA AND CWRU DEVISE NEW PROCESS
Mixing a little dry ice and a simple industrial process cheaply
mass-produces high-quality graphene nanosheets, researchers in South Korea and Case Western Reserve
University report.
Graphene, which is made from graphite, the same stuff as “lead”
in pencils, has been hailed as the most important synthetic material in a
century. Sheets conduct electricity better than copper, heat better than any
material known, are harder than diamonds yet stretch.
Scientists worldwide speculate graphene will revolutionize computing,
electronics and medicine but the inability to mass-produce sheets has blocked
widespread use.
A description of the new research will be published the week of March
26 in the online Early Edition of the Proceedings of the National Academy
of Sciences. The story is embargoed until Monday, March 26, 2012 at 3 p.m. U.S.
Eastern time
Jong-Beom Baek, professor and director of the Interdisciplinary School
of Green Energy/Advanced Materials & Devices, Ulsan National Institute of
Science and Technology, Ulsan, South Korea, led the effort.
“We have developed a low-cost, easier way to mass produce better
graphene sheets than the current, widely-used method of acid oxidation, which
requires the tedious application of toxic chemicals,” said Liming Dai, a Kent
Hale Smith professor of macromolecular science and engineering at Case Western Reserve and a co-author of the paper.
Here’s how:
Researchers placed graphite and frozen carbon dioxide in a ball miller,
which is a canister filled with stainless steel balls. The canister was turned
for two days and the mechanical force produced flakes of graphite with edges
essentially opened up to chemical interaction by carboxylic acid formed during
the milling.
The carboxylated edges make the graphite soluble in a class of solvents
called protic solvents, which include water and methanol, and another class
called polar aprotic solvents, which includes dimethyl sulfoxide.
Once dispersed in a solvent, the flakes separate into graphene
naonsheets of five or fewer layers.
To test whether the material would work in direct formation of molded
objects for electronic applications, samples were compressed into pellets. In a
comparison, these pellets were 688 times better at conducting electricity than
pellets yielded from the acid oxidation of graphite.
After heating the pellets at 900 degrees Celsius for two hours, the
edges of the ball-mill–derived sheets were decarboxylated, that is, the edges
of the nanosheets became linked with strong hydrogen bonding to neighboring
sheets, remaining cohesive. The compressed acid-oxidation pellet shattered
during heating.
To form large-area graphene nanosheet films, a solution of solvent and the edge-carboxylated graphene nanosheets was cast on silicon wafers 3.5 centimeters by 5 centimeters, and heated to 900 degrees Celsius. Again, the heat decarboxylated the edges, which then bonded with edges of neighboring pieces. The researchers say this process is limited only by the size of the wafer. The electrical conductivity of the resultant large-area films, even at a high optical transmittance, was still much higher than that of their counterparts from the acid oxidation.
By using ammonia or sulfur trioxide as substitutes for dry ice and by
using different solvents, “you can customize the edges for different
applications,” Baek said. “You can customize for electronics, supercapacitors,
metal-free catalysts to replace platinum in fuel cells. You can customize the
edges to assemble in two-dimensional and three-dimensional structures.”
US-Korea NBIT, World Class University and Basic Research Laboratory
programs through the National Research Foundation of Korea and the U.S, Air
Force Office of Scientific Research funded the research.
nice article, what is the issues with this new mass production method? if there is not any major issue, where "this kind" of graphene can be used
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