Carbonaceous nanostructured materials: obtaining, agents dopants and electrochemical applications
Keywords:
synthesis of carbonaceous materials; clays; carbon sources.Abstract
Carbonaceous materials are currently of great importance because they are used in electrochemical devices capable of storing energy from renewable sources of electricity generation. In this work, a search on the characteristics of precursors, synthesis methods and characterization of carbonaceous materials with electrochemical applications was carried out. As a result of this review is obtained that distillery vinasse and torula liquor are potential sources of carbon for the synthesis of those materials. Also those synthesis methods using templates lead to improved electrical properties, clays are the most commonly used templates for synthesis, but it is evidenced the possibility of using zeolites chemically modified with these ends. The doping with nitrogen, phosphorus and some metal oxides leads to an improvement of the electrical properties of the obtained materials.
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10. WANG, Q.; LI, H.; CHEN, L., et.al. "Monodispersed hard carbon spherules with uniform nanopores". Carbon. 2001, 39 (14), 2211-2214. ISSN: 0008-6223.
11. GÓMEZ-AVILÉS, A.; DARDER, M.; ARANDA, P., et.al. "Multifunctional materials based on graphene-like/sepiolite nanocomposites". Applied Clay Science. 2010, 47 (3-4), 203-211. ISSN: 0169-1317.
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13. WANG, Q.; LI, H.; CHEN, L., et.al"Novel spherical microporous carbon as anode material for Li-ion batteries". Solid State Ionics. 2002, 152 43-50. ISSN: 0167-2738.
14. WANG, Y.; SU, F.; WOOD, C. D., et.al. "Preparation and characterization of carbon nanospheres as anode materials in lithium-ion secondary batteries". Industrial & engineering chemistry research. 2008, 47 (7), 2294-2300. ISSN: 0888-5885
15. YANG, J.; ZHOU, X.-Y.; LI, J., et.al. "Study of nano-porous hard carbons as anode materials for lithium ion batteries". Materials Chemistry and Physics. 2012, 135 (2-3), 445-450. ISSN: 0254-0584.
16. FERNÁNDEZ‐SAAVEDRA, R.;ARANDA, P. Y RUIZ‐HITZKY, E. "Templated synthesis of carbon nanofibers from polyacrylonitrile using sepiolite". Advanced Functional Materials. 2004, 14 (1), 77-82. ISSN: 1616-301X
17. LI, J.; SHAO, C.; LI, B., et.al. "Synthesis of in-situ high nitrogen-doped helical carbonaceous nanofibers toward high-performance lithium-ion batteries". Materials Letters. 2017, 188 308-311. ISSN: 0167-577X.
18. ZALDIVAR, R. J.; KOBAYASHI, R. W.; RELLICK, G. S., Y OTROS. "Carborane-catalyzed graphitization in polyarylacetylene-derived carbon-carbon composites". Carbon. 1991, 29 (8), 1145-1153. ISSN: 0008-6223.
19. WU, Y.;FANG, S. Y JIANG, Y. "Carbon anodes for a lithium secondary battery based on polyacrylonitrile". Journal of power sources. 1998, 75 (2), 201-206. ISSN: 0378-7753.
20. HERNÁNDEZ, J. R. R.; LUEVANO, N. L.; SILVA, C. I. Z., et.al. "Obtención del carbón activado a partir de residuos de madera de la industria mueblera del estado de Aguascalientes". Conciencia Tecnológica. 2003, (23), 6. ISSN: 1405-5597.
21. TANG, K.; WHITE, R. J.; MU, X., et.al. "Hollow carbon nanospheres with a high rate capability for lithium‐based batteries". ChemSusChem. 2012, 5 (2), 400-403. ISSN: 1864-5631.
22. TANG, K.; WHITE, R. J.; MU, X., et.al. "Hollow carbon nanospheres with a high rate capability for lithium‐based batteries". ChemSusChem. 2012, 5 (2), 400-403. ISSN: 1864-5631.
23. GÓMES-AVILÉS, A.; DARDER, M.; ARANDA, P., et.al. "Multifunctional materials based on graphene-like/sepiolite nanocomposites". Applied Clay Science. 2010, 47 (3-4), 203-211. ISSN: 0169-1317.
24. SI, W.-J.; WU, X.-Z.; XING, W., et.al. "Bagasse-based nanoporous carbon for supercapacitor application". Journal of Inorganic Materials. 2011, 26 (1), 107-112. ISSN.
25.CHANFÓN CURBELO, J. M. Y LORENZO ACOSTA, Y. "Alternativas de tratamiento de las vinazas de destilería. Experiencias nacionales e internacionales". Centro azúcar. 2014, 41 (2), 56-67. ISSN: 0253-5777.
26. DOMENECH-LÓPEZ, F.; LORENZO-ACOSTA, Y.; LORENZO-IZQUIERDO, M., et.al. "Diagnóstico preliminar de las emisiones gaseosas en la industria de los derivados de la caña de azúcar". ICIDCA. Sobre los Derivados de la Caña de Azúcar. 2011, 45 (3), 30-37. ISSN: 0138-6204.
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2021-03-10
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Rodríguez-Suarez, N., Quesada-González, O., Danguillecourt-Álvarez, E., & Almenares-Verdecia, I. (2021). Carbonaceous nanostructured materials: obtaining, agents dopants and electrochemical applications. Revista Cubana De Química, 33(1), 93–116. Retrieved from https://cubanaquimica.uo.edu.cu/index.php/cq/article/view/5169
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