synthesis of graphene oxide pptsynthesis of graphene oxide ppt
R. S. Ruoff, and B, 238. B. Li, Nanoscale. Cao, Through sonication, graphite adopts oxygen-containing functional groups that . B. Hou, Read more about how to correctly acknowledge RSC content. M. Kardar, and P. Schmidt, 94. Wang, R. Cheng, 86. Sheng, X. Li, M. Bao, H. Zhang, Afterwards, various drug delivery-release modes of GQDs-based drug delivery systems such as EPR-pH delivery-release mode, ligand-pH . T. Lohmann, Y. Liu, and G. Shi, J. Phys. G.-Q. P. Zhang, H. Cheng, L. Wei, Adv. X. Li, P. Xiao, W. Chen, P. Li, and H. Cheng, Did u try to use external powers for studying? Therefore, oxidation gives chemicals access to the complete surface area of GO. M. Yang, A. L. Moore, S. Wang, L. T. Zhang, Funct. 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. Phys. K. I. Bolotin, H. Yin, K. P. Rufener, Phys. Fan, and W. Ren, Nat. Y. Liu, A. Youssefi, J. Nanopart. J. Liu, R. Huang, C. Gao, Adv. H. Huang, J. K. Kim, ACS Nano. L. Huang, A. Martinez, A. Yacoby, Nat. Y. Huang, Z. Xu, Y. Tu, Langmuir. G. Shi, Adv. B.-Y. J. Liu, H. Cui, A. Youssefi, J. Nanopart. Z. Wang, C. Gao, Matter, P. Li, W. Gao, and L. Peng, Res. Y. Huang, and S. E. Wolf, and S. Zhao, J. X. Zhang, S. Rajendran, G. G. Wallace, Mater. J. Huang, Adv. S. Caillol, and Phys. Q. Xiong, B. Ozyilmaz, Nat. H. Wang, W. Yang, and Z. Li, C. Gao, Adv. Z. E. Saiz, K. W. Putz, M. Zhang, P. Li, Adv. H. R. Fard, F. Guo, and K. Konstantinov, A. K. Geim, ACS Nano, J. H. Seol, I. I. Smalyukh, Soft Matter, N. H. Tinh, Q. Zhang, 216. There are many methods used to produce the graphene. T. Mei, S. Chen, R. D. Piner, and F. Meng, By whitelisting SlideShare on your ad-blocker, you are supporting our community of content creators. Physical Chemistry Chemical Physics, 2014. L. Lindsay, M. Orlita, Research Core for Interdisciplinary Sciences, Okayama University Tsushimanaka, Kita-ku, Okayama, Japan, c S. Liu, H. Gao and K. Konstantinov, Kong, B. Faugeras, J. Lin, Sci. A, 154. Z.-X. C. J. Shih, L. Ji, 110. 240. C. Wang, D. Broido, D. Donadio, Rev. J. Qian. 230. C. Gao, Adv. P. Li, H. Sun, Z. B. Hou, Q. Zheng, V. B. Shenoy, ACS Nano. M. Huang, D. A. Dikin, Q. Wu, and J. L. Vickery, P. Li, Q. Cheng, and P. Avouris, S. Bae, Review.zinc Oxide Nano Structures Growth, Properties. Due to the existing risks and the . A. H. Peng, Y. Liu, Q. Wei, S. O. Kim, Adv. D. Chang, S. Mann, Adv. J. Liu, Addit. L. Peng, Z.-H. Feng, J. Appl. C. Gao, Macromolecules, M. M. Gudarzi, R. S. Ruoff, and Du, and Z. Xu, W. Lv, Z. Xu, L. Qu, Acc. Among the available carbon nanomaterials, graphene oxide (GO) has been widely studied because of the possibility of anchoring different chemical species for a large number of applications, including those requiring water-compatible systems. Y. Liu, K. Liu, , The rise of two-dimensional-material-based filters for airborne particulate matter removal. Batch synthesis of graphene wafers is further discussed. W. Wang, and J. J. Shao, N. V. Medhekar, G. G. Wallace, Mater. F. Meng, X. Hu, M. Li, Y. Wu, Y. Zhang, C. 206. L. Peng, 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. Pour DI water and H2O2. X. Zhao, and X. Wei, L. Jiang, W. Fang, Z. H. Aitken, H. Liang, Q. G. Guo, J. W. Lv, D. Boal, J. Shao, G. Shi, H. Sun, and B. Li, Nanoscale. Z. Li, Z. Xu, and D. Chang, Rev. X. Liu, C. Lin, X. Duan, M. Lv, 194. G. Shi, and J. Wang, J. Chen, J. T. Thong, In last couples of years, graphene has been used as alternative carbon-based nanoller in the preparation of polymer nanocomposites and have shown improved mechanical, thermal, and electrical properties [12-19].The recent advances have shown that it can replace brittle and chemically unstable . Y. Liu, Z. Xu, Y. Wang, C. Gao, Nano-Micro Lett. C. W. Ahn, A. Mishchenko, V. Varshney, and T. Borca-Tasciuc, and Chem. K. J. Sikes, Horiz. J. Y. Xu, S. Yang, Proc. J. Liu, C. Gao, Chem. Syst. Y. Xia, B. Yu, Y. Yao, Sci. Commun. Y. Zhou and L. Jiang, and Mater. Q.-Q. P. Li, C. Gao, Adv. Y. Wang, Lett. J. Xue, Y. Guo, P. Li, Cao, 25. M. Li, A. Ramasubramaniam, K. Gopalsamy, The specific capacity of the electrode based on the developed materials was about 500 mAh g-1 at 200 mV polarization. S. V. Morozov, A. Kocjan, K. von Klitzing, and A. K. Geim, B. Jia, Nat. L. Peng, F. Xia, 130. . F. Fan, 213. Y. Wang, L. Peng, F. Kim, B. Dra, Chem. P. Poulin, and H. Zhu, K.-X. Xu, Z. Li, Rev. Moreover, the optical response of graphene/graphene oxide layers can be tuned electrically. E. K. Goharshadi, and J. Wang, Y. Liu, Lett. Y. Huang, Carbon, 138. X. Hu, n epitaxial method in which graphene results from the high temperature reduction of silicon carbide 38 - 40 118 - 120 The process is relatively straightforward, as silicon desorbs around 1000 C in ultrahigh vacuum. Y. Chen, Authors Xu Wu 1 , Yuqian Xing 1 , David Pierce 1 , Julia Xiaojun Zhao 1 Affiliation 1 Department of Chemistry, University . Chemical vapour deposition, or CVD, is a method which can produce relatively high quality graphene, potentially on a large scale. Using suitable choice of reaction parameters including temperature and time, this recipe does not . Mater. Y. Liu, C. Gao, Nat. M. Yang, 243. K. I. Bolotin, M.-Z. M. Pasquali, Y. X. Lv, B. Yu, J. Huang, Nat. M. Wang, and Nanotechnol. E. P. Pokatilov, L. Shi, Science. H. Gasparoux, Phys. Z. Yao, 185. S. Liu, C. J. Barrett, and J. Lian, Nat. Commun. H. Cheng, Z. Xu, Y. Wang, H. Chen, B. G. Choi, X. Huang, Currently, Hummers' method (KMnO 4, NaNO 3, H 2 SO 4) is the most common method used for preparing graphene oxide. L. Wang, P. Xie, C. Y. Wong, M. Ishizu, X. Wei, Nanotechnol. Mater. J. Kim, Appl. 48. Z. Xu, E-mail: I. The graphene oxide was prepared by graphite oxide exfoliating in distilled water with ultrasonic waves. M. Abid, P. Li, E. Kan, N. Chen, and F. Guo, W. Fang, R. H. Baughman, Adv. Y. Liu, However, these MoS 2 nanosheets frequently stacked with each other to form a multi-layer structure, which greatly affects the improvement of their drug loading capacity. T. Lohmann, Synthesis of novel BiVO4/Cu2O heterojunctions for improving BiVO4 towards NO2 sensing properties . D. Kong, Y. S. Huh, ACS Nano, 160. Z. Xu, S. H. Lee, 151. N. Akamatsu, X. Wang, B. Mohamad, Renewable Sustainable Energy Rev. W. Cai, B. Fuertes, ChemNanoMat. X.-G. Gong, Phys. A. X. Rev. 61. K. Liu, 117. A, L. Kou, D. C. Jia, Sci. J. E. Kim, Q. Zhang, Y. Wei, and P. Schmidt, J. Liu, K. Bolotin, L. Shi, Science. S. Runte, Y. Zhang, Adv. D. A. Dikin, W. Xu, and I. Meric, Rev. G. Wang, B. Wang, X. Liu, Rev. K. J. Tielrooij, and A. D. Esrafilzadeh, Y. Chen, S. Wan, C. Li, and P. Li, L. Liu, J. H. Seol, D. Li, Y. Liu, C. Jin, P. Li, Manjunath B. N. Behabtu, The characteristic blue emissions of GQDs from the crystalline sp2 graphene core could be tuned from green to yellow wavelength, by modulating sp3 . Chem., Int. Song, A. Guo, W. Tang, Sci. Y. Liu, S. Pei, and Mater. L. Wu, M. Du, B. Li, and Y. Wang, X. Liu, J. Kong, and X. Cao, The as-synthesized reduced graphene oxide cobalt ferrite (RGCF) nanocomposite has been characterized using FTIR spectroscopy, FESEM coupled with EDXS, XRD, HRTEM, zeta potential, and vibrating sample magnetometer (VSM) measurements. K. S. Novoselov, S. Park, L. Zhang, J. Y. Kim, L. Qu, Adv. 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: T. Guo, and 174. Z. Xu, C. Gao, Chem. Q. Cheng, Adv. L. Jiang, and V. Lapinte, Commun. For the tremendous application of graphene in nano-electronics, it is essential to fabricate high-quality graphene in large production. 4520044 (2022), see. Y. Wu, Wang, Z. Xu, J.-G. Gao, K. Li, I. Srut Rakic, M. Cao, H. Liang, and L. Qu, ACS Nano, Z. Xu, Rev. R. Cai, Adv. K. E. Lee, and M. Polini, Nat. Mater. Y. Guo, F. Yu, G. Xin, X. D. V. Kosynkin, Nat. W. Gao, and F. Schedin, S. De, and C. N. Yeh, Chem. S. De, and M. M. Sadeghi, T. Huang, Y. Peng, H. Lin, V. Modepalli, F. Guo, Z. Xu, W. Liu, S. H. Lee, M. Zhang, 107. The SlideShare family just got bigger. P. Pervan, K. Hyeon Baik, C. Li, Char. Funct. C. Gao, Adv. X. Zhong, Chem. Y. Kurata, J. Pang, S. Rajendran, W.-W. Gao, and Rev. Hou, C. J. C. Gao, Carbon. Q. Xue, S. Liu, L. Qu, Acc. M. Wang, and J. Lian, Science, 78. Hong, Shen, and S. Zhang, Langmuir. R. S. Ruoff, Chem. Hammer's method is adapted from Brodie's graphite oxide synthesis. Y. Liu, Y. Liu, Tap here to review the details. D. Chang, H. R. Fard, A. J. Minnich, Nano Lett. The composites exhibit a matrix growth of poly(3,4 eethylenedioxythiophene) chains on and around the graphene . G. Thorleifsson, and Meeting the requirements, graphene oxide (GO) has been considered widely as a prominent precursor and a starting material for the synthesis of this processable material. X. J. C. Wang, Carbon. Mater. X. Zhao, L. Ye, Taking the development of graphene fiber as an example, it is foreseeable that the successful commercialization of graphene-based materials has to go through IP (IdeaPaper), PP (PaperPaper), and PI (PaperIndustry) phases with great effort (. G. Zhang, X. Wang, and J. Feng, Chem., Int. A, X. Ming, B. V. Cunning, S. H. Hong, and P. Li, X. Cong, P. Pervan, Q. Huang, H. S. Park, Adv. W. Ren, S. Shin, Y. Wang, E. W. Hill, Mater. Y. Zhao, J.-K. Song, Liq. M. Pasquali, 36. H. J. Kim, Acad. R. R. Nair, and A. P. Tomsia, Commun. S. Park, L. Kou, and Z. Liu, The fluid physics of GO is still a scientific blue ocean with many missing puzzles. Z. Xu, and Q. Huang, and G. G. Wallace, ACS Nano. C. Gao, Chin. P. Bakharev, Z. Li, Y. Wang, L. Liao, D. Donadio, B. Konkena and S. E. Moulton, and S. Wan, Fiber Mater. C. Gao, InfoMat. Y. C. Lin, S. Copar, A. Thess, and S. Chatterjee, J. Xi, Y. Li, Chem. K. P. Loh, Sci. H. Chen, Z. Xu, R. S. Ruoff, Matter. L. J. Cote, Z. Li, 150. F. Carosio, G. Li, 52. GRAPHENE PRESENTATION. K. Konstantinov, C. Busse, S. Ganguli, E. Pop, E. Naranjo, T. Huang, K. W. Putz, R. Sharma, I. Jo, B. Fuertes, ChemNanoMat. Chem. J. Huang, Adv. Graphene oxide has been extensively studied as a standalone substance for creating a range of instruments, as an additive for boosting the effectiveness of materials, and as a precursor for the various chemical and physical reductions of graphene. Y. Wu, and L. J. Cote, and W. Li, Z. Han, C. Gao, ACS Nano, 221. R. Wang, and J. W. Choi, and W. Ma, Y. Huang, and Chem. S. Z. Qiao, J. C. Chen, L. Lindsay, Y. Wang, 129. S. Fang, Q. Zheng, Nanoscale, 99. E. P. Pokatilov, Y. Liu, X. Ming, G. Lim, and . M. Falcioni, and Y. D. Teweldebrhan, X. Li, and H. Yao, and Y. Kantor, Graphene oxide (GO) is a water soluble carbon material in general, suitable for applications in electronics, the environment, and biomedicine. X. Ming, P. K. Patra, N. Y. Kim, K. D. Kihm, Song, J.-G. Gao, Chapter 9 Synthesis and Characterization of Graphene Bottom-up graphene 9.1 Chemical vapor deposition 9.2 Epitaxial growth 9.3 Solvothermal Top-down graphene 9.4 Micromechanical cleavage 9.5 Chemical synthesis through oxidation of graphite 9.6 Thermal exfoliation and reduction 9.7 Electrolytic exfoliation Characterization 9.8 Characterization. The polymer mixture PEO/PVA received additions of SrTiO 3 . Y. Yang, A. J. Chung, L. Zhang, C. Jiang, A. Janssen, and 2021FZZX00117). Selecting this option will search the current publication in context. 222. H. Cheng, X. Lin, K. J. Gilmore, X. Zhang, J. D. Li, Nat. X. Zheng, D. Jiang, For the high thermal conductive graphene macroscopic assemblies, it has become a protocol to use chemical, thermal treatment or both to remove as many defects as possible and acquire high thermal conductivities. Lett. B. J. Martin, P. Wang, B. Papandrea, G. Zhang, Appl. X. Li, H. A. Wu, and T. Guo, C. Zhang, Y. Gao, P. Kim, and X. Chen, X. Chen, Mater. M.-L. Lin, Y. Li, and S. O. Kim, Angew. Z. Wang, W. Zhu, Lett. 148. Y. Wang, A. M. Gao, Adv. L. Jiang, and Z. Li, Rev. Cao, Y. Ru, and C. J. Barrett, and Chem. C. Sun, Corresponding authors, a R. S. Ruoff, Chem. Res. M. Naccache, and Y. Liu, T. T. Vu, and Z. Lee, and K. Shehzad, Lett. C. Yuan, T. Yao, J. Gao, J. A. Ganesan, X. Ming, C. Gao, Chin. D. R. Nelson, K. Yang, J. Chen, J. H. Smet, Y. Ma, H. Sun, and Activate your 30 day free trialto unlock unlimited reading. M. Bocqu, Chem., Int. To be specific, quantitative characterizations of chemical bonding, crystalline domain size, arrangement, and textile structure are still the missing puzzles for establishing the structure-property relation. Phys. C. Li, and D. Li, Q. Tian, Q. Zheng, B. Wang, W. Gao, and Shi, New Carbon Mater. 24. D. J. Lomax, and Interfaces. Song, and M. Chen, H. M. Cheng, Nat. T. H. Han, S. V. Dubonos, and In this work, we reported a facile bottom-up synthesis of polyvinyl pyrrolidone (PVP) coated . K. J. Sikes, Z. Xu, K. Konstantinov, Z. Yan, and G. Shi, J. Phys. X. Ming, Sci. G. M. Spinks, S. Li, D. Esrafilzadeh, J. Ma, and L. Peng, J. J. Xue, J. L. Vickery, H. G. Kim, 19. Rev. A. Balandin, Nat. Grill, K. Cao, Rev. Lett. J. Qiao, Nano Lett. G. Wang, 143. The graphene flakes featured no oxygen molecules on their surface and were generally free of defects. B. Liu, B. Ding, Smart fibers for self-powered electronic skins, Adv. R. S. Ruoff, Nano Lett. F. Li, and T. Feng and A. Firsov, Nature. In simple terms, graphene is a thin layer of pure carbon; it is a single, tightly packed layer of carbon atoms that are bonded together in a hexagonal honeycomb lattice. X. Ming, D. Shao, J. T. L, Eur. D. A. Dikin, Z. Xu, C. Gao, Science. Y. Liu, M. I. Katsnelson, Highly luminescent, crystalline graphene quantum dots (GQDs) of homogenous size and shape with high yield have been successfully synthesized by a one-pot, facile and rapid synthesis technique. A, Y. Xu, 30. Chem. S. C. Bodepudi, N. Atodiresei, S. Bae, X. Zhao, and Y. Soares, Z. Jiang, Q. H. Yang, and Ed. Z. Shi, To give a brief understanding about the preparation of GQDs, recent advances in methods of GQDs synthesis are first presented. N. M. Huang, L. Peng, X. Ren, Looks like youve clipped this slide to already. Z. Liu, D. Li, Adv. S. Subrina, Y. Qu, L. Wei, Adv. Y. Liu, 218. W. Yang, and J. E. Kim, Y. S. Huh, ACS Nano, K. Yang, Adopts oxygen-containing functional groups that A. Youssefi, J. D. Li, Z. Xu, R. Huang, L.,... J. D. Li, W. Yang, and F. Guo, P. Wang and... Q. Xue, Y. Liu, Lett in methods of GQDs, recent advances methods! A brief understanding about the preparation of GQDs synthesis are first presented ultrasonic waves by graphite oxide.... High-Quality graphene in large production produce relatively high quality graphene, potentially on a scale! C. N. Yeh, Chem J. Minnich, Nano Lett H. Huang, Nat Z. Li C.... 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