Graphene () is an allotrope of carbon consisting of a single layer of atoms arranged in a two-dimensional honeycomb lattice. The name is a portmanteau of "graphite" and the suffix -ene, reflecting the fact that the graphite allotrope of carbon consists of stacked graphene layers.Each atom in a graphene sheet is connected to its three nearest neighbors by a σ-bond, and contributes one electron to a conduction band that extends over the whole sheet. This is the same type of bonding seen in carbon nanotubes and polycyclic aromatic hydrocarbons, and (partially) in fullerenes and glassy carbon. These conduction bands make graphene a semimetal with unusual electronic properties that are best described by theories for massless relativistic particles. Charge carriers in graphene show linear, rather than quadratic, dependence of energy on momentum, and field-effect transistors with graphene can be made that show bipolar conduction. Charge transport is ballistic over long distances; the material exhibits large quantum oscillations and large and nonlinear diamagnetism. Graphene conducts heat and electricity very efficiently along its plane. The material strongly absorbs light of all visible wavelengths, which accounts for the black color of graphite; yet a single graphene sheet is nearly transparent because of its extreme thinness. The material is also about 100 times stronger than would be the strongest steel of the same thickness.
Scientists theorized the potential existence and production of graphene for decades. It has likely been unknowingly produced in small quantities for centuries, through the use of pencils and other similar applications of graphite. It was originally observed in electron microscopes in 1962, but only studied while supported on metal surfaces. The material was later rediscovered, isolated and characterized in 2004 by Andre Geim and Konstantin Novoselov at the University of Manchester, who were awarded the Nobel Prize in Physics in 2010 for their research on the material. High-quality graphene proved to be surprisingly easy to isolate.
The global market for graphene was $9 million in 2012, with most of the demand from research and development in semiconductor, electronics, electric batteries, and composites.
The IUPAC (International Union for Pure and Applied Chemistry) recommends use of the name "graphite" for the three-dimensional material, and "graphene" only when the reactions, structural relations or other properties of individual layers are discussed. A narrower definition, of "isolated or free-standing graphene" requires that the layer be sufficiently isolated from its environment, but would include layers suspended or transferred to silicon dioxide or silicon carbide.
Is there any simple justification about graphene having no band gap? How bout its linear E-K? Why bilayer graphene has a quadratic E-K and electric field can open a band gap there?
I do not completely understand the broken symmetry argument? Also Why MoS2 which has similar structure, do not...
Hi all. Is there any place where I can check how to derive the DOS of bilayer graphene subject to an external field. I have got the Hamiltonian right and solved the eenrgies but then I am not sure how to obtain the DOS right..
Thanks
Are there any "graphene" Planck-scale quantum gravity?
I'm wondering if there is any QG or emergent structure that is "graphene" due to suggestions from this paper, specifically,
does LQG, SF, CDT,M-theory, etc., suggest space consists of discrete points arranged in a non-cubic lattice...
I'm taking a graduate course on computational physics which has a project. I'm doing research
on electronic properties of graphene, like quantum hall effect measurements. So, I want to do the project related to my research.
The project shouldn't be too difficult, as I haven't done simulations...
Hi,
In the book of Hanson, the dispersion relationship for a graphene near K points are approximated by
E=hbar.vF.k where hbar-> reduced Planck's constant vF->Fermi velocity k-> wave number
and then it is said that, since this is similar to the energy of a photon
E=hbar.c.k where...
Hello all,
I have read a few papers lately that have used DFT based techniques to investigate metallic adatom adsorption on top of graphene (see for instance PRB 77, 235430 2008). I was under the impression that electrons in graphene are described by the Dirac equation and not the...
Hey everyone,
So I've been doing research in graphene for a semester and my colleague and I have had no luck making graphene samples.
We are using the "scotch-tape" method on Kish graphite. We use a small piece of one flake to put on weak tape (we find that the Magic Tape is too strong...
Hi all,
according to textbook definition the effective mass of a particle in a periodic potential is
\frac{\hbar^2}{m*} = \frac{d^2}{d k^2} E(k)
where E(k) is the energy dispersion.
Is this definition applicable at a generic point of a band, or only at the center and edge of the Brillouin...
Hello all,
I am beginning a new research project involving graphene. Although I have be actively doing a literature search on graphene, I was wondering if somebody would be will to suggest a good textbook that covers the basic of graphene
Thanks in advance
-Ed
Hello. I'm trying to find the individual contributions of carbon atoms to the charge carriers in graphene. In other words, I'm trying to answer "How many charge carriers does one carbon atom supply?"
Here is what I've done so far:
Taking the max. carrier density as 10^13 1/cm^2 and the...
Interesting article I read on how the highly-conductive graphene also begins to exhibit some semiconductive properties at very narrow dimensions:
http://www.technologyreview.com/Nanotech/20119/
http://physicsworld.com/cws/article/news/32539
Gee, I wonder if this could keep Moore's Law going?