GRAPHENE NANORIBBONS Nahid Shayesteh,
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1 USC Department of Physics Graduate Seminar GRAPHENE NANORIBBONS Nahid Shayesteh,
2 Outlines 2 Carbon based material Discovery and innovation of graphen Graphene nanoribbons structure and...
3 FUNCTIONS 3 Carbon-based nanoelectronics. 1. Replace silicon-based micro electronics 2. Exhibit superior physical properties in many aspects. 3. Industrial applications
4 History 4 The term graphene 1962 Hanns-Peter Boehm coined graphene as a combination of graphite and the suffix ene to describe single-layer carbon foils. Hanns-Peter Boehm: Born January 9, 1928 in Paris German Chemist Professor Emeritus in Ludwig-Maximillians University in Munich,Germany Pioneer of graphene research
5 Innovation Mitsutaka Fujita ( 藤田光孝 Fujita Mitsutaka) 5 Introduced graphene nanoribbons as a theory model to examine the edge and nanoscale size effect in graphene. Japanese Physicist Born: August 16, 1959 Died: March 18, 1998
6 Terminology Definition: thin strips of graphene 6 Graphene nanoribbons GNR s Nano-graphene ribbons
7 The structure of Graphene consists of Honeycomb Lattice 2 Dimension thin layer of Carbon atoms Lattice Structure 7 Basic structure of carbon hexagon of graphene
8 Chemical Structures The carbon-carbon bond length in graphene is about nanometers. Graphene sheets stack to form graphite. One stack of 3 million sheets = 1 millimeter thick. Graphene is the basic structural element of some carbon allotropes including Graphite Charcoal Carbon Nanotubes Fullerence 8 Nahid Shayesteh, PhD Candidate, M.S.C., B.S.
9 Energy Gap The Energy gap of the 1 dimensional graphene nanoribbons (GNRs), can be Produced lithographically by patterning 2 dimensional graphene through a chemical route Different crystallographic orientations Tuned with varying widths 9 Nahid Shayesteh, PhD Candidate, M.S.C., B.S.
10 In Theory 10 Graphene projections Display hopeful electronic properties. Possess very high electron or hole mobility (comparable to the properties observed in CNTs) Graphene is considered a semimetal, because There is no present band gap (band gap is zero), There is a narrow channel width (transverse direction) & a band gap can be provided.
11 Graphenenanoribons (GNRs) can be obtained by unzipping the single wall carbon nanotubes. 11 Nahid Shayesteh, PhD Candidate, M.S.C., B.S.
12 The ribbon form of graphene (GNR) 12 Inherited almost all of the attractive properties of the carbon nanotube and graphene. Additional benefit of a tunable band gap. Electronic Properties Tunable semiconducting behaviors vis a vis changing ribbon width. The first bandgap measurements are made by... Phaedon Avouris. Philip Kim Opening of energy gaps Reported: 0.5 ev in a 2.5 nm wide armchair ribbon
13 Electronic Properties Zigzag & Armchair GNRs are metallic or semiconducting electronic properties that depends on the width of the nanoribbon. Electronic properties depend on the edge shape 1. armchair 2. zigzag 13
14 Armchair GNR s 14 Liang work shows certain armchair GNRs can display semiconducting behavior. Armchair ribbon is semiconducting when N=3p or N=3p+1 #of dimer lines N=3p+2 is semimetal behavior (p is integer).
15 Zigzag GNR s 15 Zigzag GNRs are either 1. Semiconducting 2.Metallic And Expected to be more conductive
16 Conclusion 16 New types of the graphene base material can be achieved. Carbon based material have different application depend on their structure
17 References 17 1.Bu, H., et al., Atomistic simulations of mechanical properties of graphene nanoribbons. Physics Letters A, (37): p Eduardo V Castro1, N.M.R.P., J M B Lopes dos Santos1, and F.G.a.A.H.C. Neto4, Bilayer graphene: gap tunability and edge properties. Journal of Physics, (1): p (8). 3.connor, O., Liu,, CNTFET Modeling and Recongurable Logic-Circuit Design. Ieee Transactions on Circuits and Systems, (11): p Group, C.M., Moore' s Law: More or Less. www. cmg.org/measureits/issues/mit41/m_41 2.html, Novoselov, K.S., Electronic properties of graphene. phys. stat. sol., (11 / DOI /pssb ): p
18 18 Thank you for your time and consideration. I will be more than happy to answer any questions or concerns that you may have at this time.
GRAPHENE NANORIBBONS Nahid Shayesteh,
USC Department of Physics Graduate Seminar 1 GRAPHENE NANORIBBONS Nahid Shayesteh, Outlines 2 Carbon based material Discovery and innovation of graphen Graphene nanoribbons structure Application of Graphene
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