Known as the "Wonder Material", Graphene are one atom thick sheets of graphite. It is one of the thinnest and strongest material ever measured. It's structure when viewed on the atomic scale would resemble chicken wire. Graphene was discovered by Andre Geim and Konstantin Novoselov at the University of Manchester who shared the 2010 the Nobel Prize for Physics for the discovery.
In the publication, Nature Materials, the two scientists in the March 2007 issue defined graphene as "a flat monolayer of carbon atoms tightly packed into a two-dimensional (2D) honeycomb lattice, and is a basic building block for graphitic materials of all other dimensionalities. It can be wrapped up into 0D fullerenes, rolled into 1D nanotubes or stacked into 3D graphite."
Graphene's history can be traced back as early as 1859 when D.C. Brodie was aware of the highly lamellar structure of thermally reduced graphite oxide and in 1948 when G. Ruess and F. Vogt published The earliest TEM images of few-layer graphene. It was only in 2004 that Geim and Novoselov isolated graphene using adhesive tape.
Research into graphene are moving in different directions. Similar to plastics with varied uses, graphene show promise in a lot of applications such as:
Now, researchers in South Korea and Case Western Reserve University have found a cheap process to mass produce high-quality graphene nanosheets using dry ice and a simple industrial process. A graphene nanosheet is a flexible material that can be rolled or molded into objects or devices used for electronic and other applications.
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 online in the Early Edition of the Proceedings of the National Academy of Sciences.
Video: A Primer on Graphene
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, 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.
Video: Traditional Way on How To Make Graphene
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."
In the publication, Nature Materials, the two scientists in the March 2007 issue defined graphene as "a flat monolayer of carbon atoms tightly packed into a two-dimensional (2D) honeycomb lattice, and is a basic building block for graphitic materials of all other dimensionalities. It can be wrapped up into 0D fullerenes, rolled into 1D nanotubes or stacked into 3D graphite."
Graphene's history can be traced back as early as 1859 when D.C. Brodie was aware of the highly lamellar structure of thermally reduced graphite oxide and in 1948 when G. Ruess and F. Vogt published The earliest TEM images of few-layer graphene. It was only in 2004 that Geim and Novoselov isolated graphene using adhesive tape.
Research into graphene are moving in different directions. Similar to plastics with varied uses, graphene show promise in a lot of applications such as:
- High speed microchips at 1000+ GHZ
- Solar Cells
- Enhanced Plastics
- Super Rapid DNA Sequencing
- Spintronic Computer Applications
- Ultracapacitors
- Replacement For Silicon Transistors
- Sensing and Detecting Molecules
- Next-Gen Displays
Now, researchers in South Korea and Case Western Reserve University have found a cheap process to mass produce high-quality graphene nanosheets using dry ice and a simple industrial process. A graphene nanosheet is a flexible material that can be rolled or molded into objects or devices used for electronic and other applications.
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 online in the Early Edition of the Proceedings of the National Academy of Sciences.
Video: A Primer on Graphene
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, 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.
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.
Video: Traditional Way on How To Make Graphene
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."
RELATED LINKS
Case Western Reserve University
Proceedings of the National Academy of Sciences
Interdisciplinary School of Green Energy
National Research Foundation of Korea
Air Force Office of Scientific Research
Nature Materials
New Use For Graphene Discovered: Distillation
The Wonders of Graphene
Famous Scientists of the 21st Century
NASA Develops Material That Is Blacker Than Black
Advances in Lithium Ion Batteries: 1 Week Power on a 15 Minute Charge
Solar Paint That Can Generate Electricity
What Does 4G Technology Do For Mobile Phones?
New Advance in Antimatter: CERN ALPHA Group Measures Antihydrogen
CERN News: Solar Thermal Panels Made With CERN Technology
Engineers Discover New Way To Produce Economic and Efficient Solar Panels
Application of Nanotechnology and Thermodynamics in Measuring Devices
New Way in OLED Production
Aerogels