Hostname: page-component-586b7cd67f-rdxmf Total loading time: 0 Render date: 2024-11-27T11:14:28.489Z Has data issue: false hasContentIssue false

Influence of high-temperature treatment of granular activated carbon on its structure and electrochemical behavior in aqueous electrolyte solution

Published online by Cambridge University Press:  31 January 2011

Stanisław Biniak*
Affiliation:
Nicolaus Copernicus University, 87-100 Toruń, Poland
Maciej Pakuła
Affiliation:
Naval University of Gdynia, 81-103 Gdynia, Poland
Andrzej Świątkowski
Affiliation:
Military University of Technology, 00−908 Warsaw, Poland
Michał Bystrzejewski
Affiliation:
Warsaw University, 02-093 Warsaw, Poland
Stanisław Błażewicz
Affiliation:
University of Mining and Metallurgy, 30-059 Cracow, Poland
*
a)Address all correspondence to this author. e-mail: [email protected]
Get access

Abstract

Activated carbon Norit R3-ex (demineralized) was annealed at various temperatures (950–2700 °C) in an argon atmosphere. The changes of the porosity of the products were characterized on the basis of N2 adsorption isotherms (at 77 K). The texture of the samples was investigated by x-ray diffraction, Raman spectroscopy, and scanning electron microscopy. The presence of surface oxygen (Fourier transform infrared) and its content in the surface layer (from energy dispersive spectroscopy) were determined. The electrical resistivity of powdered samples was measured. Cyclovoltammetry of carbon (powdered electrodes) were carried out and the electrical double-layer capacitances were estimated from the cyclic voltammetry curves. Heat treatment increased the degree of crystallization of the samples, which was correlated with changes in their conductivity. A rapid drop in porosity (at 1800–2100 °C) took place in parallel with a decrease in the electrical double layer capacity. The presence of surface oxygen as a result of oxygen chemisorption on freshly annealed carbon samples was confirmed using several methods.

Type
Articles
Copyright
Copyright © Materials Research Society 2010

Access options

Get access to the full version of this content by using one of the access options below. (Log in options will check for institutional or personal access. Content may require purchase if you do not have access.)

References

REFERENCES

1.Kowalczyk, Z., Sentek, J., Jodzis, S., Diduszko, R., Presz, A., Terzyk, A., Kucharski, Z., Suwalski, J.Thermally modified active carbon as support for catalysts for NH3 synthesis. Carbon 34, 403 (1996)Google Scholar
2.Forni, L., Molinari, D., Rossetti, I., Pernicone, N.Carbon-supported promoted Ru catalyst for ammonia synthesis. Appl. Catal., A 185, 269 (1999)CrossRefGoogle Scholar
3.Zheng, X.L., Zhang, S.J., Xu, J.X., Wei, K.Effect of thermal and oxidative treatments of activated carbon on its surface structure and suitability as a support for barium-promoted ruthenium in ammonia synthesis catalysts. Carbon 40, 2597 (2002)Google Scholar
4.Yi, B., Rajagopalan, R., Burket, C.L., Foley, H.C., Liu, X.M., Eklund, P.C.High temperature rearrangement of disordered nanoporous carbon at the interface with single wall carbon nanotubes. Carbon 47, 2303 (2009)Google Scholar
5.Błażewicz, S., Świątkowski, A., Trznadel, B.J.The influence of heat treatment on activated carbon structure and porosity. Carbon 37, 693 (1999)CrossRefGoogle Scholar
6.Ptrobst, N., Grivei, E.Structure and electrical properties of carbon black. Carbon 40, 201 (2002)Google Scholar
7.Biniak, S., Świątkowski, A., Pakuła, M.Electrochemical studies of phenomena at active carbon-electrolyte solution interfacesChemistry and Physics of Carbon edited by L.R. Radovic Vol. 27 (Marcel Dekker Inc, New York 2001)125Google Scholar
8.Card, J.C., Valentin, G., Storck, A.The activated carbon electrode: A new, experimentally verified mathematical model for the potential distribution. J. Electrochem. Soc. 137, 2736 (1990)Google Scholar
9.Bansal, R.C., Goyal, M.Activated Carbon Adsorption (CRC Press Taylor & Francis, LLC,, Boca Raton, FL 2005)CrossRefGoogle Scholar
10.Lastoskie, C., Gubbins, K.E., Quirke, N.Pore-size distribution analysis of microporous carbons: A density-functional theory approach. J. Phys. Chem. 97, 4786 (1993)CrossRefGoogle Scholar
11.Tan, P.H., Dimovski, S., Gogotsi, Y.Raman scattering of non-planar graphite: Arched edges, polyhedral crystals, whiskers and cones. Philos. Trans. R. Soc. London, Ser. A 362, 2289 (2004)Google Scholar
12.Dong, J., Shen, W., Zhang, B., Liu, X., Kang, F., Gu, J., Li, D., Chen, L.P.New origin of spirals and new growth process of carbon whiskers. Carbon 39, 2325 (2001)CrossRefGoogle Scholar
13.Fialkov, A.S., Smirnov, B.N., Bondarenko, N.V., Zaichikov, S.G., Polyakova, N.V., Mikhailova, V.A., Baver, A.I.Investigation of the structure of carbon fibres by means of the scanning electron microscopy. Mech. Compos. Mater. 8, 811 (1972)Google Scholar
14.Li, Z.Q., Lu, C.J., Xia, Z.P., Zhou, Y., Luo, Z.X-ray diffraction patterns of graphite and turbostratic carbon. Carbon 45, 1686 (2007)Google Scholar
15.Iwashita, N., Park, C.R., Fujimoto, H., Shiraishi, M., Inagaki, M.Specification for a standard procedure of x-ray diffraction measurements on carbon materials. Carbon 42, 701 (2004)Google Scholar
16.Tuinistra, F., Koenig, J.L.Raman spectrum of graphite. J. Chem. Phys. 53, 1126 (1970)Google Scholar
17.Ferrari, A.C., Robertson, J.Interpretation of Raman spectra of disordered and amorphous carbon. Phys. Rev. B 61, 14095 (2000)Google Scholar
18.Yoshida, A., Kaburagi, Y., Hishiyama, Y.Full width at half-maximum intensity of the G band in the first order Raman spectrum of carbon material as a parameter for graphitization. Carbon 44, (11)2333 (2006)Google Scholar
19.Ferrari, A.C., Rodil, S.E., Robertson, J.Interpretation of infrared and Raman spectra of amorphous carbon nitrides. Phys. Rev. B 67, 155306 (2003)Google Scholar
20.Baldan, M.R., Almeida, E.C., Azevedo, A.F., Golcaves, E.S., Rezende, M.C., Ferreira, N.G.Raman validity for crystallite size L a determination on reticulated vitreous carbon with different graphitization index. Appl. Surf. Sci. 254, (2)600 (2007)CrossRefGoogle Scholar
21.Biniak, S., Pakuła, M., Świątkowski, A., Walczyk, M.Studies on chemical properties of activated carbon surfaceCarbon Materials: Theory and Practice edited by A.P. Terzyk, P.A. Gauden, andP. Kowalczyk (Research Signpost, Trivandrum, India 2008)51Google Scholar
22.Biniak, S., Szymański, G.S., Siedlewski, J., Świątkowski, A.The characterization of activated carbons with oxygen and nitrogen surface groups. Carbon 35, 1799 (1997)CrossRefGoogle Scholar
23.Vinke, P., van der Eijk, M., Verbee, M., Voskamp, A.F., van Bekkum, H.Modification of the surfaces of a gas activated carbon and a chemically activated carbon with nitric acid, hypochlorite, and ammonia. Carbon 32, 675 (1994)Google Scholar
24.Zawadzki, J.Infrared spectroscopy in surface chemistry of carbonsChemistry and Physics of Carbon edited by P.A. Thrower Vol. 21 (Marcel Dekker, New York 1988)147Google Scholar
25.Venter, J.J., Vannice, M.A.Applicability of “drifts” for the characterization of carbon-supported metal catalysts and carbon surfaces. Carbon 26, 889 (1988)Google Scholar
26.Thomas, J.M., Evans, E.L., Barber, M., Swift, P.Determination of the occupancy of valence bands in graphite, diamond and less-ordered carbons by x-ray photo-electron spectroscopy. Trans. Faraday Society 67, 1875 (1971)Google Scholar
27.Randin, J.P., Yeager, E.Differential capacitance study on basal plane of stress-annealed pyrolytic-graphite. J. Electroanal. Chem. 36, 257 (1972)Google Scholar
28.Espinola, A., Miguel, P.M., Salles, M.R., Pinto, A.R.Electrical properties of carbons—Resistance of powdered materials. Carbon 24, 337 (1986)CrossRefGoogle Scholar
29.Sanchez-Gonzalez, J., Macias-Garcia, A., Alexandre-Franco, M.F., Gomez-Serrano, V.Electrical conductivity of carbon blacks under compression. Carbon 43, 741 (2005)Google Scholar
30.Kennedy, L.J., Vijaya, J.J., Sekaran, G.Electrical conductivity study of porous carbon composite derived from rice husk. Mater. Chem. Phys. 91, 471 (2005)CrossRefGoogle Scholar
31.Radeke, K-H., Backhaus, K.O., Swiatkowski, A.Electrical conductivity of activated carbons. Carbon 29, 122 (1991)Google Scholar
32.Barton, S.S., Koresh, J.E.A study of the surface oxides on carbon cloth by electrical conductivity. Carbon 22, 481 (1984)Google Scholar
33.Polovina, M.Surface characterization of oxidized activated carbon cloth. Carbon 35, 1047 (1997)Google Scholar
34.Liu, C-C., Walters, A.B., Vannice, M.A.Measurements of electrical properties of a carbon black. Carbon 33, 1699 (1995)Google Scholar
35.Kinoshita, K.Carbon: Electrochemical and Physicochemical Properties (Wiley, New York 1988)Google Scholar
36.Kastening, B., Hahn, M., Rabanus, B., Heins, M., Felde, U.Electronic properties and double layer of activated carbon. Electrochim. Acta 42, 2789 (1997)Google Scholar
37.Portet, C., Yushin, G., Gogotsi, Y.Electrochemical performance of carbon onions, nanodiamonds, carbon black and multiwalled nanotubes in electrical double layer capacitors. Carbon 45, 2511 (2007)CrossRefGoogle Scholar
38.Portet, C., Chmiola, J., Gogotsi, Y., Park, S., Lian, K.Electrochemical characterizations of carbon nanomaterials by the cavity microelectrode technique. Electrochim. Acta 53, 7675 (2008)Google Scholar
39.Bleda-Martinez, M.J., Macia-Agullo, J.A., Lozano-Castello, D., Morallon, E., Cazorla-Amoros, D., Linares-Solano, A.Role of surface chemistry on electric double layer capacitance of carbon materials. Carbon 43, 2677 (2005)Google Scholar
40.Frackowiak, E., Beguin, F.Carbon materials for the electrochemical storage of energy in capacitors. Carbon 39, 937 (2001)Google Scholar
41.Hsish, C.T., Teng, H.Influence of oxygen treatment on electric double-layer capacitance of activated carbon fabrics. Carbon 40, 667 (2002)CrossRefGoogle Scholar