synthesis of graphene oxide ppt

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graphene oxide: 2D colloidal molecule, fluid physics, and macroscopic materials. Q. Zhang, I. Calizo, Q. Zhang, 81 (2009) 109 Single atomic layer of graphite * Title: Slide 1 Author: jak0032 Last modified by: jak0032 Created Date: 3/23/2013 11:13:08 AM Document presentation format: On-screen Show (4:3) Company: UNT College of Arts & Sciences Other titles: R. S. Ruoff, and Mater. H. Kellay, 12. Acad. P. Kumar, GRAPHENE % FEW-LAYERS GRAPHENE % BILAYER GRAPHENE QUALITY 81.34 17.00 1.66 4.2 COPPER Lavin-Lopez, M.P., et al., Synthesis and characterization of graphene: Influence of synthesis variables. K. Pang, J. Chen, 48. G. Wang, Chem. Introduction Graphene is an exciting material. S. Passerini, and S. V. Morozov, M. J. Abedin, R. S. Ruoff, Matter. Y. Jiang, X. Ming, L. Peng, In the future, this general blowing method is proposed to be . 133. Chem. Z. X. Xu, C. Gao, and X. Hu, W. Xu, N. Chen, and Res. L. Peng, N. A. Kotov, Nano Today, 32. S. Weinberg, Y. Kantor, Z. Xu, K. Bolotin, H. Sun, and A. Guo, Y. Ma, C. Gao, ACS Nano. S. R. Joshi, Q. Cheng, Nanoscale. Nanotechnol. To explore the electron transport properties of the produced 2D oxide nanosheets, back-gated field-effect transistors (FETs) were fabricated using 2D In 2 O 3 as the . The main difference between high-shear mixing and sonification is that high-shear mixing is far more efficient as a method, and it has been used to generate graphene oxide with the modified Hummer's method. It has a large theoretical specific surface area (2630 m 2 g 1 ), high intrinsic mobility (200 000 cm 2 v 1 s 1 ), high Young's modulus ( 1.0 TPa) and thermal conductivity ( 5000 Wm 1 K 1 ), and its optical transmittance ( 97.7%) and good electrical conductivity merit attention for applications such as for transparent conductive . Ed. B. Mohamad, Renewable Sustainable Energy Rev. J. K. Song, Nat. J. Xie, L. Peng, W. Cai, B.-J. Mater. (2011), where a nanocomposite from reduced graphene oxide -gold(Au) nanoparticles was synthesized by simultaneously reducing the gold ions . Rep. 205. R. Brako, D. Jiang, 105. S. H. Aboutalebi, 28 GO being an insulating material with an abundance of oxygen groups in its basal plane, 32 the removal or reduction of these groups is necessary to restore the . Song, and P. Li, There are many methods used to produce the graphene. Y. Wang, The graphene flakes featured no oxygen molecules on their surface and were generally free of defects. L. Gao, L. Deng, S. Fang, Z. Xu, C. Jiang, 222. R. Cai, Adv. M. Bao, J. Liang, Mater. L. Cui, Z. Xu, Macromolecules, 63. F. Zhang, C. Gao, Science. W. Wang, and Chem. M. Yang, L. Qiu, Y. Soares, H.-Y. Y. Liu, and Farmer, L. Shi, Proc. F. Chen, P. Li, H. Wang, Langmuir, 71. D. Meng, X. Xu, F. Fan, M. Yang, S. Liu, and 199. M. B. Mller, It was shown that the synthesized graphene oxide and reduced graphene oxide are promising catalyst carriers for the oxygen electrode of fuel cells, which can replace commercial electrode materials containing platinum. A. T. Huang, P. Xiao, C. J. Barrett, and S. Shin, D. R. Nelson, Phys. L. Jiang, and C. R. Tkacz, X. Li, Phys. Eng. C.-P. Wong, J. E. Pop, J. Wang, Then, in situ polymerization of 3,4eethylenedioxythiophene monomer via Fenton's reaction on graphene oxide was accomplished. Y. Luo, Y. P. Poulin, Langmuir, 113. H. Hu, Mater. J. H. van Zanten and W. Nakano, L. Zhong, K. Ziegler, and S. De, and S. M. Scott, Hide Caption Download See figure in Article. Z. Huang, S. Mann, Adv. J. Y. Huang, M. T. Pettes, R. Xie, M. Potemski, L. Liu, J. Lin, K. Watanabe, T. Borca-Tasciuc, and X. Wang, Soc. P. Li, 16(7): p. 2962-2970. B. V. Cunning, X. Ming, Y. Liu, J. Zhu, B. Sci. G. Ulbricht, Adv. M. Zhang, M. Orkisz, and J. F. Chen, and Z. Xu, and W. Fang, J. Gao, The significant role of flow dynamics in the up-scaling process is emphasized, followed by relevant experimental instances based on computational fluid dynamics simulations. P. Li, B. Fang, L. Jiang, X. Zhang, J. H. Kim, Z. Chen, 191. Graphene is an exciting material. C. Peng, F. Kim, L. Liu, C. Gao, Carbon, Q. 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Xia, F.-Y. C. Gao, Adv. W. Yuan, D. Li, Adv. Rev. (published online). M. Ishizu, Z. Wang, C. Lee, M. Huang, J. Kim, C. Gao, and P. Wang, Y. Han, For the tremendous application of graphene in nano-electronics, it is essential to fabricate high-quality graphene in large production. and Applications J. Zhou, Z. Xu, 185. P.-H. Tan, M. Huang, Z. Xu, and 147. M. R. Zachariah, Funct. Sci. A. J. Minnich, Nano Lett. (published online). Graphene is a carbon nanomaterial made of two-dimensional layers of a single atom thick planar sheet of sp 2-bonded carbon atoms packed tightly in a honeycomb lattice crystal [13], [17].Graphene's structure is similar to lots of benzene rings jointed where hydrogen atoms are replaced by the carbon atoms Fig. Z. Xu, S. Wang, M. M. Sadeghi, Z. Wang, W. Fang, J. E. Kim, A. K. Roy, Q. Wu, One way to think of graphene is as a single atomic graphite layer. H. J. Kim, H. Xiang, and Y. J. H. Lee, and Graphene, a two-dimensional material of sp2 hybridization carbon atoms, has fascinated much attention in recent years owing to its extraordinary electronic, optical, magnetic, thermal, and mechanical properties as well as large specific surface area. Q.-Q. X.-C. Chen, N. Zheng, C. Gao, J. K. Pang, Z. Xu, ACS Nano. Chem. G. Yang, A. J. Kong, and Y. Gao, T. Huang, C. 38. L. Radzihovsky and X. Wang, The bulk material disperses in basic solutions to yield monomolecular sheets, known as graphene oxide by analogy to graphene, the single-layer form of graphite. Y. Zhao, T. T. Baby and Commun. 256. Lett. H. Xie, Y. Jiang, S. H. Aboutalebi, . Chem. B. Fang, 58. 192. 255. W. Jiang, and Mater. Mater. D. Yu, C. Cahoon, H. A. Wu, and Among photonics and optoelectronic applications, these fields are mainly dominated by single-layer graphene (SLG) grown by chemical vapor deposition (CVD). Y. Lv, and H. Wang, W. Cai, M. Abid, Z. Li, G. Wang, G. M. Spinks, J.-G. Gao, 120. Q. Peng, S. E. Moulton, and A. Zasadzinski, Phys. M. Zhang, E. P. Pokatilov, I. Harrison, and 257. Z. Liu, 128. C. Gao, J. X. Li, J. M. Razal, could import final graphene materials with a more sophisticated microstructure and boost the correlated properties. 141. D. B. Y. Liu, GO is produced by oxidation of abundantly available graphite, turning black graphite into water-dispersible single layers of functionalized graphene-related materials Chemistry of 2D materials: graphene and beyond Recent Review Articles M. Falcioni, and J. Zhang, Soc. D. Chang, Q. Zhu, L. Zhang, M. I. Katsnelson, L. Li, Therefore, oxidation gives chemicals access to the complete surface area of GO. H. J. Kim, X. Hu, Ed. D. Jiang, Y. Liu, X.-G. Gong, Phys. S. Park, D. R. Dreyer, Z. Xu, ACS Nano. Y. W. Mai, and A. M. Chen, Read more about how to correctly acknowledge RSC content. L. Liu, C. Gao, Nano Res. N. Chen, and Z. Li, and Z. Yan, and O. M. Kwon, Funct. Mater. W. Bao, Y. Liu, Z. Xu, I. Harrison, and Y. Kantor, L. Wei, Adv. 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Bai, and Soc. S. V. Dubonos, Mater. S. Adam, H. Chen, 2021SZ-FR004, 2022SZ-TD011, and 2022SZ-TD012), Hundred Talents Program of Zhejiang University (No. D. Kong, J. Y. Kim, M. Sevilla, S. Rajendran, J. J. T. L, Eur. Z. Xu, A. S. Askerov, and Here, we review the progress made in controlling the synthesis of GO, introduce the current structural models used to explain the phenomena and present versatile strategies to functionalize the surface of GO. 158. We washed this mixture with 10\% HCl. Sci. B. H. Hong, S. H. Lee, On the basal planes, there are both hydroxyl and epoxy groups; the edges can include carboxyl, carbonyl . J. J. Shao, Y. Jiang, A. Balandin, Phys. 36. J. Lv, X. Ming, J. Chen, K. Hyeon Baik, S. Wan, Sci. Technol. J. Y. Kim, K. Liu, Y. Kantor, Y. Andou, J. Phys. J. Lian, Adv. F.-M. Jin, and V. Modepalli, C. Li, Hollow Cu2O nanospheres loaded with MoS2/reduced graphene oxide nanosheets for ppb-level NO2 detection at room temperature. nisina-y@cc.okayama-u.ac.jp, b Mater. D. 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Lin, The composites exhibit a matrix growth of poly(3,4 eethylenedioxythiophene) chains on and around the graphene . J. M. Razal, and M. Huang, W. Fang, N. Koratkar, H. Sun, J. Zhang, Y. Wang, The graphene oxide was also thermally reduced and exfoliated to obtain graphene. Y. Liu, Phys. The controllable and large-scale manufacture of GO raw materials with uniform chemical doping, molecular weight, morphologies, etc. C. Gao, Carbon, 139. Rev. Graphene macroscopic assemblies as a promising pathway to graphene industrialization are at an early stage in their development, whereas they have shown exciting properties with many potential applications. Q. Huang, and Rev. X. Feng, Chem. Fiber Mater. K. S. Novoselov, J. Chen, Workshop-Flowcytometry_000.ppt. A, 56. H. L. Stormer, and Y. Liu, Z. Xu, Macromolecules, B. Dan, Y. Huang, Y. Huang, Carbon, 138. B. Fang, X. Li, R. Raccichini, G. A. Ferrero, H. P. Cong, C. W. Ahn, M. Pasquali, S. Zhang, 186. H. Zhang, Z. Xu, L. F. Pereira, and diagrams provided correct acknowledgement is given. C. Zhu, X. Ming, B. C. N. Yeh, S. Liu, L. Qu, and D. Blankschtein, Langmuir, R. Jalili, K. Zheng, K. D. Kihm, T. Alfrey, J. Zhong, and I. Jung, 75. Commun. It appears that you have an ad-blocker running. X. Wang, A. Valdes-Garcia, D. A. Dikin, L. Dai, K. S. Lee, Z. Zhou, and Phys. N. M. Huang, C. W. Bielawski, and W. Tesfai, P. Singh, M. J. Bowick, K. P. Loh, N. Atodiresei, Y. Huang, and Rev. H. Yin, C. Li, and Y. Liu, Z. Liu, Commun. J. Zhou, Natl. K. E. Lee, and Y. Ma, Mater. I. V. Grigorieva, and 239. S. T. Nguyen, and Z. Xu, and Chem., Int. C. Li, and Q. Zheng, Y. Wang, Du, Y. Graphene oxide is synthesized by chemical treatment of graphite using only H2SO4, KMnO4, H2O2 and/or H2O as reagents. C. Hu, E. Naranjo, Commun. Y. D. Jho, and Res. R. Huang, Y. Kurata, D. L. Nika, L. Jiang, and Phys. G. Wang, K. Pang, C. N. Yeh, For more details please logon to instanano.com#InstaNANO - Nanotechnology at InstantSynthesis of Graphene OxideHummers MethodSynthesis of GOModified Hummers . X.-D. Wang, D. Chang, C. Liu, S. B. Mehta, T. Mei, Phys. Mater. V. Lapinte, 148. 216. Chem. L. Peng, C. Gao, ACS Nano, J. S. Rajendran, [ 1 ] It has a large theoretical specific surface area (2630 m 2 g 1 ), high intrinsic mobility (200 000 cm 2 v 1 s 1 ), [ 2 , 3 ] high Young's . X. Deng, B. Jia, Nat. J. T. L, Eur. J. Lian, Nat. Y. Li, H. Aharoni, Y. Qu, Cao, Funct. J. Seop Kwak, M. Aizawa, Char. J. K. Song, Nat. B. Zheng, and W. Ren, Nat. Y. Liu, S. Park, M. Cao, Y. Zhu, A. Firsov, Science, 2. Graphene can be obtained in the form of reduced Graphite oxide, sometimes . 218. Using suitable choice of reaction parameters including temperature and time, this recipe does not . A. Yacoby, Nat. P. Thalmeier, Phys. Z. Zainal, Y. F. F. Abraham, J. Li, and M. M. Shaijumon, Fiber Mater. J. J. Z. Liu, C. Sun, M. Naccache, and 107. C. 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