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Warianty tytułu
Graphene - methods of manufacturing and its application and properties
Języki publikacji
Abstrakty
Dokonano przeglądu literatury dotyczącej metod otrzymywania grafenu. Omówiono różne sposoby otrzymywania tego materiału, a także jego pochodnych, takich jak tlenek grafenu. Szczególną uwagę zwrócono na metodę bezpośredniej eksfoliacji grafitu. Przedstawiono również najważniejsze możliwości zastosowania grafenu i jego pochodnych.
A review of the literature on methods of obtaining graphene was performed. Various methods for the preparation of graphene and its derivatives such as graphen oxide, were discussed. In particular, the attention was paid to a direct method of graphite’s exfoliation. The main possibilities of the use of graphene and its derivatives were also presented.
Wydawca
Czasopismo
Rocznik
Tom
Strony
128--136
Opis fizyczny
Bibliografia 56 poz., rys.
Twórcy
autor
- Instytut Chemicznej Przeróbki Węgla, Zabrze
autor
- Instytut Chemicznej Przeróbki Węgla, Zabrze
Bibliografia
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- 32. Liu J., Jeong H., Liu J., Lee K, Park J.Y., Ahn Y.H., Lee S., Reduction of functionalized graphite oxides by trioctylphosphine in non-polar organic solvents. Carbon, 2010, t. 48, s. 2282.
- 33. Cao Y., Feng J., Wu P., Alkyl-functionalized graphene nanosheets with improved lipophilicity. Carbon, 2010, t. 48, s. 1683.
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- 36. Shen J., Li T., Long Y, Shi M, Li N., Ye M., One-step solid state preparation of reduced graphene oxide. Carbon, 2012, t. 50, s. 2134.
- 37. McAllister M.J., Li, J.-L., Adamson D.H., Schniepp H.C., Abdala A.A., Liu J., Herrera-Alonso M., Milius D.L., Car R., Prud’homme R.K., Aksay A.A., Single sheet functionalized graphene by oxidation and thermal expansion of graphite. Chemistry of Materials, 2007, nr 19, 4396.
- 38. Arsat R., Breedon M, Shafiei M., Spizzir iP.G., Gilje S., Kaner R.B., Kalantar-Zadeh K, Wlodarski W., Graphene-like nano-sheets for surface acoustic wave gas sensor applications. Chemical Physics Letters, 2009, nr 467, s. 344.
- 39. Jung I., Dikin D., Park S., Cai W., Mielke S.L., Ruoff R.S., Effect of water vapour on electrical properties of individual reduced graphene oxide sheets. Journal of Physical Chemistry C, 2008, nr 112, s. 20264.
- 40. Fowler J.D., Allen M.J., Tung V.C., Yang Y, Kaner R.B., Weiller B.H., Practical chemical sensors from chemically derived graphene. ACS Nano, 2009, nr 3, s. 301.
- 41. Lu G.H., Ocola L.E., Chen J.H., Gas detection using low-temperature reduced graphene oxide sheets. Applied Physics Letters, 2009, nr 94(8), s. 083111.
- 42. Robinson J.T., Perkins F.K., Snow E.S., We iZ., Sheehan P.E., Reduced Graphene Oxide Molecular Sensors. Nano Letters, 2008, nr 8, s. 3137.
- 43. Pacile D., Meyer J.C., Rodriguez A.F., Papagno M., Gomez-Navarro C., Sundaram R.S., Burghard M., Kern K., Carbone C., Kaiser U., Electronic properties and atomic structure of graphene oxide membranes. Carbon, 2011, t. 49, s. 966.
- 44. Sheng K, Xu Y., Li Ch., Shi G., High-performanceself-assembled graphene hydrogels prepared by chemical reduction of graphene oxide. New Carbon Materials, 2011, t. 26, s. 9.
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- 46. Hernandez Y, Nicolosi V, Lotya M., Blighe F.M., Sun Z., De S., McGovern I.T., Holland B., Byrne M., Gun’Ko Y.K., Boland J.J., Niraj P., Duesberg G., Krishnamurthy S., Goodhue R., Hutchison J., Scardaci V, Ferrari A.C., Coleman J., High-yield production of graphene by liquid-phase exfoliation of graphite, Nature Nanotechnology, 2008, nr 3, s. 563.
- 47. Liu Ch., Hu G., Gao H., Preparation of few-layer and single-layer graphene by exfoliation of expandable graphite in supercritical N,N-dimethylformamide. Journal of Supercritical Fluids, 2012, nr 66, s. 99.
- 48. Wajid A.S., Das S., Irin F., Ahmed H.S.T., Shelburne J.L., Parviz D., Fullerton R.J., Jankowski A.F., Hedden R.C., Greek M.J., Polymer-stabilized graphene dispersions at high concentrations in organic solvents for composite production. Carbon, 2012, t. 50, s. 526.
- 49. Dhakate S.R., Chauhan N., Sharma S., Tawale J., Singh S., Sahare P.D., Mathur R.B., An approach to produce single and double layer graphene from re-exfoliation of expanded graphite. Carbon, 2011, t. 49, s. 1946.
- 50. Oh S.Y., Kim S.H., Chi Y.S., Kang T.J., Fabrication of oxide-free graphene suspension and transparent thin films using amide solvent and thermal treatment. Applied Surface Science, 2012, nr 258, s. 8837.
- 51. Guardia L., Fernandez-Merino M.J., Paredes J.I., Solis-FernandezP, Villar-Rodil S., Martinez-Alonso A., Tascon J.M.D., High-throughput production of pristine graphene in an aqueous dispersion assisted by non-ionic surfactants. Carbon, 2011, t. 49, s. 1653.
- 52. Kakaei K, One-pot electrochemical synthesis of graphene by the exfoliation of graphite powder in sodium dodecyl sulfate and its decoration with platinum nanoparticles for methanol oxidation. Carbon, 2013, t. 51, s. 195.
- 53. Yang H., Hernandez Y., Schlierf A., Felten A., Eckmann A., Johal S., Louette P.,Pireaux J.-J., Feng X., Muellen K, Palermo V., Casiraghi C., A simple method for graphene production based on exfoliation of graphite in water using 1 -pyrenesulfonic acid sodium salt. Carbon, 2013, t. 51, s. 357.
- 54. Bourlinos A.B., Georgakilas V., Zboril R., Steriotis T.A., Stubos A.K., Trapalis Ch., Aqueous-phase exfoliation of graphite in the presence of polyvinylpyrrolidone for the production of water-soluble graphenes. Solid State Communications, 2009, nr 149, s. 2172.
- 55. Lai L., Chen L., Zhan D., Sun L., Liu J., Lim H.S., Poh K.C., Shen Z., Lin J., One-step synthesis of NH2-graphene from in situ graphene - oxide reduction and its improved electrochemical properties. Carbon, 2011, t. 49, s. 3250.
- 56. Hu H., Zhao Z., Zhau Q., Gogotis Y, Qiu J., The role of microwave absorption on formation of graphene from graphite oxide. Carbon, 2012, t. 50, s. 3267.
Typ dokumentu
Bibliografia
Identyfikator YADDA
bwmeta1.element.baztech-c1987423-0486-4bfa-a9e2-87bda73cef01