1 / 23

Graphene

Graphene. A modern material with unique physical and electrical properties that could reshape our future. By: Steven Douglas 4/24/15. Outline:. Introduction to graphene. History. Physical properties. Electrical properties. Other properties. How graphene is created.

jlavoie
Télécharger la présentation

Graphene

An Image/Link below is provided (as is) to download presentation Download Policy: Content on the Website is provided to you AS IS for your information and personal use and may not be sold / licensed / shared on other websites without getting consent from its author. Content is provided to you AS IS for your information and personal use only. Download presentation by click this link. While downloading, if for some reason you are not able to download a presentation, the publisher may have deleted the file from their server. During download, if you can't get a presentation, the file might be deleted by the publisher.

E N D

Presentation Transcript

  1. Graphene A modern material with unique physical and electrical properties that could reshape our future. By: Steven Douglas 4/24/15

  2. Outline: • Introduction to graphene. • History. • Physical properties. • Electrical properties. • Other properties. • How graphene is created. • Graphene’s current uses. • Batteries • Capacitors • Transistors • Graphene’s future. • Challenges surrounding graphene. • Summary/Conclusion • Key concepts. • References.

  3. Introduction to Graphene • The first 2-dimensional material ever discovered. • One-atom thick of carbon atoms arranged in a hexagonal lattice. • Found in graphite, coal, and created in other fashions. • Hard to manufacture in large quantities, just about all graphene produced is used for R&D within companies and universities. • The strongest, lightest, and most conductive material known to man.

  4. Graphene’s short history: • Discovered by Andre Geim and Konstantin Novoselov in 2004, however this is apparently debatable. • First conceived in 1946. But they didn’t believe it could be created at room temperature. • Graphene as we know it was theoretically mentioned as recent as 1984 to describe the layers of graphite. • The term “Graphene” was used mainly In working with Carbon Nano-tubes.

  5. Amazing Physical Properties: • The strongest material ever measured. Up to 150X stronger than the equivalent weight of steel. • Pliable as rubber and has the ability to stretch up to 120% of its length then recover its original shape. • Extremely light weight, its said that a single sheet of Graphene covering a whole football field would weigh less than 1g.

  6. Electrical Properties • Graphene is classified as a zero-overlap semi-metal, which means that either holes or electrons are charge carriers. • Very high electrical conductivity when exposed to an electric field. • In a vacuum, it had a mobility that was up to 250X that of Si. Out conducts copper by a thousand times. • Effective mass at the Dirac point is zero for both electrons and holes.

  7. Other Properties: • Only known substance that is completely impermeable to gas. • Graphene oxide reportedly has the ability to attract radioactive material. • Safer creation of “Quantum Dots”. Reduces the price from $1million a kg to $100 a ton. • Also has some optical properties that are being tested as we speak. • Graphene has the ability to transmit up to 98% of light.

  8. How graphene is created:Mechanical Exfoliation • Typically involves scotch tape. • Stick the tape to a graphite block. • Use another piece of tape and stick the two sticky sides together. Repeat this process 20-100x • Press the piece of tape with the graphene on a substrate.

  9. Chemical exfoliation • The block graphite is submerged into a solvent. • An ultrasound is used to cause a splitting effect within the graphite structure. • Prolonged exposure causes little platelets to be formed. • Enriched by a centrifuge.

  10. CE via graphene oxide • Uses the same process as chemical exfoliation but graphene is oxidized. • After the CE process, it is then deposited on substrate and reduced to parent graphene in some fashion.

  11. Chemical Vapour Deposition • The most common practice in creating graphene today. • Typically a copper substrate is exposed to a low pressure, 1000˚C annealing process. • Methane and Hydrogen gas flows through the furnace. • Carbon atoms from Methane deposite on the copper, creating a continuous graphene sheet.

  12. Silicon Carbide • A small amount of silicon carbide is placed in a box with a hole in it. • The box is sealed in a vacuum or argon gas and heated to 1500˚C. • Si molecules evaporate from the surface leaving a layer of graphene.

  13. Graphene’s current uses: • In early 2014 I.B.M announced that it had built the first integrated circuit for wireless devices. • Today a tennis racquet with a graphene layer has been manufactured. • Graphene is an ingredient to conductive inks for printing circuitry. • Samsung is reportedly releasing a screen that employs Graphene to deliver current to the display.

  14. Optical Electronics • Believed to mainly be used in touchscreens, OLED, and LCD. • Graphene matches Indium-Tin Oxide performance in its basic state.

  15. Energy storage • Graphene is being experimented in both supercapacitor and battery construction.

  16. Energy storage cont. • Graphene based supercapacitors have potential to replace small batteries. • Uses the chemical exfoliation discussed earlier. • Was able to light LED’s with a two minute charge for around twelve hours.

  17. Graphene & Transistors • Clocked at 427 Ghz. • Create a false band gap by employing “Negative” resistance. • Another type of FET uses dual gate construction.

  18. Graphene’s future • Biomedical Engineering • Optical Electronics • Ultra-Filtration • Composite Materials • Photo-Voltaic cells • Energy Storage • Radioactive Clean-up

  19. Challenges Surrounding Graphene • Graphene has no bandwidth, which means it cannot be shut off. • A very hydrophobic material • Very expensive and hard to manufacture for most companies. • When deployed it seemed that the results weren’t duplicated. • Graphene is hard to produce in large usable sheets. Small flakes are what we use to test usually.

  20. Conclusion • Graphene has many obstacles to work around before it can be implemented into today’s technology. • Researchers are suggesting that it’s a matter of months rather than years for the next graphene break through. • Graphene has so many amazing properties, so expect it to impact many types of technologies.

  21. References: • http://www.sciencedaily.com/releases/2012/09/120910082304.htm • De la Fuente, Jesus. www.graphene.com.13 April 2015 • Colapinto, John. “Graphene may be the most remarkable substance ever discovered. But what is it for?”.The New Yorker, 22 December, 2014.Web.13 April, 2015 • Wang, Brian.”Graphene Hybrid Supercapacitors storing as much as lead acid batteries which is six times commercial supercapacitors” www.nextbigfuture.com 17 April, 2015. Web 20 April, 2015. • Johnson, Dexter. “Graphene circuit competes head to head with Si technology.”www.spectrum.ieee.org 3 February, 2014.Web.20 April, 2014. • Malasarn, Davin. “UCLA Researchers develop new technique to scale up production of graphene micro super capacitors”. www.newsroom.ucla.edu. 19 February, 2013.Web. 20 April, 2015

  22. Key Concepts • The first 2-D material ever discovered, only measuring 1-atom thick. • Lightest material ever discovered. • Strongest material ever discovered per unit weight. • Best electrical/thermal conductivity discovered at room temperature. • Currently does not possess a band-gap like a Si gate does.

  23. Questions?

More Related