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Nano-graphene

Figure 5.10 (Left) Schematic representation of PEG functionalization on nano-graphene sheet (NGS) through carboxylic group and subsequent label by Cy7 fluorescence marker. (Right) Photos of tumors on mice after various treatments indicated. The laser-irradiated tumor on the NGS injected mice was completely destroyed. Reproduced with permission from [179]. Figure 5.10 (Left) Schematic representation of PEG functionalization on nano-graphene sheet (NGS) through carboxylic group and subsequent label by Cy7 fluorescence marker. (Right) Photos of tumors on mice after various treatments indicated. The laser-irradiated tumor on the NGS injected mice was completely destroyed. Reproduced with permission from [179].
Kim K-B, Lee C-M, Choi J. Catalyst-free direct growth of triangular nano-graphene on all substrates. J Phys Chem C 2011 115 14488-93. [Pg.178]

Scheme 13 Iterative Diels-Alder/deprotection strategy for the synthesis of nano-graphene 47 [35]... Scheme 13 Iterative Diels-Alder/deprotection strategy for the synthesis of nano-graphene 47 [35]...
The method was pushed to the extreme with the synthesis of a giant 222 carbon graphite sheet 63 by the Mullen group [41]. Two strategies were presented to access such a nano-graphene structure. The first pathway relied on a combination of Diels-Alder reactions involving cyclopentadienone derivatives and alkynes 61, and a cyclotrimerization of alkyne 62. The second strategy relied exclusively on... [Pg.130]

Scheme 43 Synthesis of nano-graphene using cross-coupling, Diels-Alder, and dehydrogenation reactions [107]... Scheme 43 Synthesis of nano-graphene using cross-coupling, Diels-Alder, and dehydrogenation reactions [107]...
Scheme 44 Preparation of a nano-graphene ribbon via Suzuki cross-coupling reaction [108]... Scheme 44 Preparation of a nano-graphene ribbon via Suzuki cross-coupling reaction [108]...
Jang BZ, Zhamu A (2012) Process for producing dispersible and conductive nano graphene platelets from non-oxidized graphitic materials. Patent US 2010/8216541... [Pg.307]

Zhamu A (2011) Mass production of pristine nano graphene materials. Patent WO/2011/ 014,347... [Pg.307]

Somani PR, Somani SP, Umeno M (2006) Planer nano-graphenes from camphor by CVD. Chem Phys Lett 430 56... [Pg.56]

It is expected that enlarging the aromatic macrocycle would enhance the columnar order due to intense, intermolecular n-n interactions and, thus, increase the charge carrier mobility. Hexa-peri-hexabenzocoronene (HBC) is one of the largest and most symmetrical of all-benzenoid polycyclic aromatic hydrocarbons, that function as a core fragment for DLCs. Hexa-peri-hexabenzocoronene contains 42 carbon atoms and 13 phenyl rings, so it can be considered as a nano-graphene. Mullen... [Pg.127]

The growth pathway of various fullerene- and graphene-type nano-objects may be related. They are synthesized in the vapor phase and often appear simultaneously on the same sample. A common growth mechanism with similar nucleation seeds may, therefore, lead to these different structures. [Pg.65]

The ID electronic energy bands for carbon nanotubes [170,171, 172, 173, 174] are related to bands calculated for the 2D graphene honeycomb sheet used to form the nanotube. These calculations show that about 1/3 of the nano tubes are metallic and 2/3 are semiconducting, depending on the nanotube diameter di and chiral angle 6. It can be shown that metallic conduction in a (ra, m) carbon nanotube is achieved when... [Pg.91]

X. Wang, L. Zhi, K. Mullen, Transparent, conductive graphene electrodes for dye-sensitized solar cells, Nano Letters, 8 (2008) 323-327. [Pg.36]

T.J. Booth, P. Blake, R.R. Nair, D. Jiang, E.W. Hill, U. Bangert, et al., Macroscopic graphene membranes and their extraordinary stiffness, Nano Letters, 8 (2008) 2442-2446. [Pg.36]

A.A. Balandin, S. Ghosh, W. Bao, I. Calizo, D. Teweldebrhan, F. Miao, et al., Superior thermal conductivity of single-layer graphene, Nano Letters, 8 (2008) 902-907. [Pg.37]

H.A. Becerril, J. Mao, Z. Liu, R.M. Stoitenberg, Z. Bao, Y. Chen, Evaluation of solution-processed reduced graphene oxide films as transparent conductors, ACS Nano, 2 (2008)... [Pg.38]

Electronic transport properties of individual chemically reduced graphene oxide sheets, Nano Letters, 7 (2007) 3499-3503. [Pg.38]

G. Williams, B. Seger, P. V Kamat, Ti02-graphene nanocomposites. UV-assisted photocatalytic reduction of graphene oxide, ACS Nano, 2 (2008) 1487-1491. [Pg.38]

A.A. Green, M.C. Hersam, Solution phase production of graphene with controlled thickness via density differentiation, Nano Fetters, 9 (2009) 4031-4036. [Pg.39]

P.N. Nirmalraj, T. Lutz, S. Kumar, G.S. Duesberg, J.J. Boland, Nanoscale mapping of electrical resistivity and connectivity in graphene strips and networks, Nano Letters. 11 (2011) 16-22. [Pg.39]

X. Sun, D. Luo, J. Liu, D.G. Evans, Monodisperse chemically modified graphene obtained by density gradient ultracentrifugal rate separation, ACS Nano, 4 (2010) 3381-3389. [Pg.39]

R.S. Weatherup, B. Dlubak, S. Flofmann, Kinetic control of catalytic CVD for high-quality graphene at low temperatures, ACS Nano, 6 (2012) 9996-10003. [Pg.40]

R.S. Weatherup, B.C. Bayer, R. Blume, C. Ducati, C. Baehtz, R. Schlogl, et al., In situ characterization of alloy catalysts for low-temperature graphene growth, Nano Letters, 11 (2011) 4154-4160. [Pg.40]

Characterization of graphene films and transistors grown on sapphire by metal-free chemical vapor deposition, ACS Nano, 5 (2011) 8062-8069. [Pg.40]

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See also in sourсe #XX -- [ Pg.127 ]



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