Emphasizing Physical Aspects and Applications of Graphenes
Keywords:
graphene, synthesis methods, structure, properties
Abstract
Graphenes have attracted much attention due to their properties and possible applications. This approach is dedicated to shortly describe the problems related to this promising element. Some aspects concerning physical description and material characteristics are discussed. The paper presents methods for graphenes obtaining and major means of morphological investigation and structural characterization. Also, mechanical, thermal and tribological properties are reviewed. Finally, concluding remarks are drown.
References
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[24]. Park S. et al. - Aqueos suspension and characterization of chemically modified graphene sheets. Chemistry of Materials 20:6592-6596, (2008).
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[26]. Gomez N.C., et al. - Elastic properties of chemically derived single graphene sheets. Nano Letters 8:2045-2049, (2008).
[27]. Penuelas J., et al. - Surface morphology and characterization of thin grapheme films on SiC: effect of substrate. Physical Revue B 79:876-890, (2009).
[28]. Marchetto D., et al. - Friction and wear on single-layer epitaxial graphene in multi-asperity contacts. Triblogy Letters 48:77-82, (2012).
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[2]. Singh, V., Joung D. - Graphene based materials: Past, present and future. Progress in Materials Science 56:1178-1271, (2011).
[3]. Stankovich, S., et al. - Synthesis of graphene based nanosheets via chemical reduction of exfoliated graphite oxide. Carbon 12:1558-2003, (2007).
[4]. Schniepp H.C., et al. - Functionalized single graphene sheets derived from splitting graphite oxide. The Journal of Physical Chemistry B 110:8535-8539, (2006).
[5]. Faccio R., et al. - Mechanical properties of graphene nanoribbons. Journal of Physics: Condensed Matters 21:1 -29. (2009).
[6]. Li X., et al.2008. Highly conducting sheets and LangmuirBlodgett films. Nano Letters 538-541.
[7]. Georgantzinos S.K., et al. - Graphene characterization: a fully non-linear spring-based finite element prediction. Physica E 43:1833-1839, (2011).
[8]. Alzebdeh K. - Evaluation of the in-plane effective elastic moduli of single-layered graphene sheet. Journal of Mechanics and Materials in Design. 8:269-278, (2012).
[9]. Tkachev S.V., et al. - Reduced graphene oxide. Inorganic Materials 48:796-802, (2012).
[10]. Xianoqing S., et al. - A simple method for preparing graphene nano-sheets at low temperature. Advanced Powder Technology 24:317-323, (2013).
[11]. Li-Yu et al. - Friction and wear characteristics of multi-layer graphene films investigated by atomic force microscopy. Surface&Coating Technology 205:4864-4869, (2011).
[12]. Yi - Tao. - High-concentration organic solutions of poly(styrene-cobutadiene-co-styrene)-modified graphene sheets exfoliated from graphite. Carbon 49:3259-3537, (2011).
[13]. Park, G.S. et al. - G’band Raman spectra of single, double and triple layer graphene. Carbon 47:1303-1321, (2009).
[14]. Paredes J.L.,et al. - Atomic force and scanning tunneling microscopy imaging of graphene nanosheets derived from graphite oxide. Langmuir 17:5957-5982, (2009).
[15]. Myer J.C., et al. - Direct imaging of lattice atoms and topological defects in grapheme membranes. Nano Letters 4:3582-3590, (2008).
[16]. Gas M.H., et al. 2008. Free-standing graphene at atomic resolution. Nature Nanotechnology5: 676- 681.
[17]. Lee, C.,et al. - Measurement of the elastic properties and intrinsic strength of monolayer graphene. Science 385-388, (2008).
[18]. Balandin A., et al. - Superior thermal conductivity of single layer graphene. Nano Letters 8:902 -907, (2008).
[19]. Yanwu Z., et al. - Graphene and Graphene Oxide: Synthesis, Properties, and Applications. Advanced Materials 22:3906-3924, (2010).
[20]. Reina A., et al. - Large Area, Few-Layer Graphene Films on Arbitrary Substrates by Chemical Vapor Deposition. Nano Letters 9:30-35, (2008).
[21]. Changgu, L.,et al. - Measurement of the elastic properties and intrinsic strength of monolayer graphene. Science 321:385-397, (2008).
[22]. Drayer D.,et al. - The chemistry of graphene oxide. Chemical Society Rewiews 39:228-240, (2009).
[23]. Wu G., et al. - I–V Curves of graphene nanoribbons under uniaxial compressive and tensile strain. Chemical Physics Letters 559:82-97, (2013).
[24]. Park S. et al. - Aqueos suspension and characterization of chemically modified graphene sheets. Chemistry of Materials 20:6592-6596, (2008).
[25]. Bunch, J.S., - Adhesion mechanics of graphene membranes. Solid State Communications 152:1359-1364, (2012).
[26]. Gomez N.C., et al. - Elastic properties of chemically derived single graphene sheets. Nano Letters 8:2045-2049, (2008).
[27]. Penuelas J., et al. - Surface morphology and characterization of thin grapheme films on SiC: effect of substrate. Physical Revue B 79:876-890, (2009).
[28]. Marchetto D., et al. - Friction and wear on single-layer epitaxial graphene in multi-asperity contacts. Triblogy Letters 48:77-82, (2012).
[29]. Kim H., et al. - Graphene/polyetylene nanocomposites: Effect of polyetylene functionalization and blending methods. Polymer 52:1837-1846, (2011).
Published
2013-06-15
How to Cite
1.
BASTIUREA M, RODEANU MS, DIMA D, ANDREI G. Emphasizing Physical Aspects and Applications of Graphenes. The Annals of “Dunarea de Jos” University of Galati. Fascicle IX, Metallurgy and Materials Science [Internet]. 15Jun.2013 [cited 20Apr.2024];36(2):59-3. Available from: https://www.gup.ugal.ro/ugaljournals/index.php/mms/article/view/2841
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