Carbon electrochemical properties

IJ K. Kinoshita, Carbon Electrochemical and Physicochemical Properties, John Wiley, New York, 1988, p. 20. 

A similar, but highly porous, vitreous carbon material—reticulated vitreous carbon (RVC)—has found widespread application for flow analysis and spectro-electrochemistry (25). As shown in Figure 4-10, RVC is an open-pore ( spongelike ) material such a network combines the electrochemical properties of glassy carbon with many structural and hydrodynamic advantages. These include a very high surface area ( 66 cm2 cm-3 for the 100-ppi grade), 90-97% void volume, and a low resistance to fluid flow. 

For example, the final heat treatment temperatures In the manufacture will produce different electrochemical properties, even with the same surface treatments (2-4) since the structure and electrical property of glassy carbon depends on the temperature, as Indicated by the single crystal TEM patterns and by measurement of temperature dependent conductivity (5-6). On the other hand. It Is also well established that the electrochemical properties of carbon-based electrodes are markedly affected by surface treatments. 

Manganese and iron oxidation are coupled to cell growth and metabolism of organic carbon. Microbially deposited manganese oxide on stainless and mild steel alters electrochemical properties related to the potential for corrosion. Iron-oxidizing bacteria produce tubercles of iron oxides and hydroxides, creating oxygen-concentration cells that initiate a series of events that individually or collectively are very corrosive. 

Metal oxides. Noble metals are covered with a surface oxide film in a broad range of potentials. This is still more accentuated for common metals, and other materials of interest for electrode preparation, such as semiconductors and carbon. Since the electrochemical charge transfer reactions mostly occur at the surface oxide rather than at the pure surface, the study of electrical and electrochemical properties of oxides deserves special attention. 

The electrochemical properties of fluorographite are also interesting in connection with the electrolysis of melted KF-2HF, which is used for industrial production of fluorine. Fluorine is here evolved at the carbon anode, which is spontaneously covered with a passivating layer of fluorographite hence it causes an undesired energy loss during the electrolysis. 

Electronically conducting polymers (ECPs) such as polyaniline (PANI), polypyrrole (PPy) and po 1 y(3.4-cthy 1 cncdi oxyth iophcnc) (PEDOT) have been applied in supercapacitors, due to their excellent electrochemical properties and lower cost than other ECPs. We demonstrated that multi-walled carbon nanotubes (CNTs) prepared by catalytic decomposition of acetylene in a solid solution are very effective conductivity additives in composite materials based on ECPs. In this paper, we show that a successful application of ECPs in supercapacitor technologies could be possible only in an asymmetric configuration, i.e. with electrodes of different nature. 

Although some nanostructured carbons are able to store reversibly higher amounts of lithium than graphite [2], they generally demonstrate a high hysteresis (see for example Figure 2) that still precludes their use in lithium-ion batteries. In order to improve their electrochemical properties as electrode materials, a current effort is made to better understand the... 

Thus, the electrochemical properties of the individual carbon materials are not so high as to enable their commercial usage in Li-ion batteries. In order to improve the performance, we started making composite materials from two individual carbon ingredients. Figure 1 shows a typical result of electrochemical tests of an electrode made of a blend of graphite and soft carbon treated at 1100°C (Cl 100) in comparison with the discharge curves of the individual constituents. 

Electrochemical Properties of Modified Carbons in the Reaction of Oxygen Reduction... 

In order to determine the electrochemical properties of the solvent, the electrode process in molten carbamide and in carbamide-MeCl (where Me - NH4, K) mixtures on inert electrodes (platinum, glassy carbon) were investigated using cyclic voltammetry. The electrode reaction products were analysed by spectroscopic methods. The adsorbtion of carbamide- NH4CI anodic product was investigated by differential capacity method. 

CNTs have been one of the most actively studied electrode materials in the past few years due to their unique electronic and mechanical properties. From a chemistry point of view, CNTs are expected to exhibit inherent electrochemical properties similar to other carbon electrodes widely used in various electrochemical applications. Unlike other carbon-based nanomaterials such as C60 and C70 [31], CNTs show very different electrochemical properties. The subtle electronic properties suggest that carbon nanotubes will have the ability to mediate electron transfer reactions with electroactive species in solution when used as the electrode material. Up to now, carbon nanotube-based electrodes have been widely used in electrochemical sensing [32-35], CNT-modified electrodes show many advantages which are described in the following paragraphs. 

J. Li, A. Cassell, L. Delzeit, J. Han, and M. Meyyappan, Novel three-dimensional electrodes electrochemical properties of carbon nanotube ensembles. J. Phys. Chem. B 106, 9299-9305 (2002). 

For convenience and simplicity, the electrochemical study of electrode materials is normally made in hthium/(electrode material) cells. For carbonaceous materials, a lithium/carbon cell is made to study electrochemical properties, such as capacity, voltage, cycling life, etc.. Lithium/carbon coin cells use metallic lithium foil as the anode and a particular carbonaceous material as the... 

Although little information has been available for the effect of a-silyl substitution on the electrochemical properties of heteroatom compounds, extensive studies have been carried out on the effect of /f-silyl substitution [10,13]. For the -substituted heteroatom compounds (substitution at the a carbon), the introduction of a silyl group results in a significant decrease of the oxidation potentials, although the magnitude depends upon the nature of the heteroatom. This effect is explained in terms of the interaction between the C Si a orbital and the nonbonding p orbital of the heteroatom (Fig. 5). This interaction raises the HOMO level which in turn favours the electron transfer. 

Although platinum is the metal of choice for PEM fuel cell cathodes, Paul Matter, Elizabeth Biddinger, and Umit Ozkan (Ohio State University) show that nonprecious metals will have to be developed for this type of fuel cell to become practical and widely used. Although few materials have the electrochemical properties needed to replace platinum, this review discusses candidates such as macrocycle compounds, non-marcrocyclic pyrolyzed carbons, conducting polymers, chalcogen-ides, and heteropolyacids. 

Z. Wu, W. Feng, Y. Feng, Q. Liu, X. Xu, T. Senkino, A. Fuji, M. Ozaki, Preparation and characterization of chitosan-grafted multiwalled carbon nanotubes and their electrochemical properties, Carbon, vol. 45, pp. 1212-1218, 2007. 

Jiang, L. and L. Gao, Fabrication and characterization of carbon nanotube-titanium nitride composites with enhanced electrical and electrochemical properties. Journal of the American Ceramic Society, 2006. 89(1) p. 156-161. 

Cao et al. produced HTC/Sn nanocomposites by hydrothermal treatment of sucrose and SnCl4 solution [37]. After the carbon was removed, the electrochemical properties of the hollow Sn02 materials were tested. This material has a high initial dis-... 

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