Subject graphitized carbon

Electron irradiation (100 keV) of the sample, heated to 800°C, yields MWCNTs (20-100 nm in length) attached to the surface. Such nanotube growth does not take place if natural graphite, carbon nanoparticles or PTFE are subjected to electron irradiation. The result implies that the material may be a unique precursor for CNTs and may constitute a new preparation method. 

Structure Carbon subjected to +1300°C in helium atmosphere, resulting in a graphite-like structure in the form of polyhedra, with virtually no unsaturated bonds, ions, lone electron pairs, or free radicals Analytical Properties Especially for use in microbore columns suggested for lower aromatics but with some potential for higher-molecular-mass compound separations Reference 7-10... 

The transition from amorphous carbon-containing deposits to graphite-like species and finally to graphitic carbon typically proceeds via polyaromatic heterocycles (Guisnet and Magnoux, 2001), which are not easily detected by conventional Raman spectroscopy because of fluorescence problems (Chua and Stair, 2003 Li and Stair, 1996). The use of UV excitation provides a powerful means to circumvent fluorescence problems and tackle the identification of the carbonaceous deposits (Chua and Stair, 2003). This subject was discussed in detail by Stair (2007). Polyaromatic deposits were burned off very quickly upon restoration of oxidizing conditions (Boulova et al., 2001 Mul et al., 2003 Puurunen and Weckhuysen, 2002 Puurunen et al., 2001). 

Many studies report the effect of porosity and surface area on metal dispersion and catalytic activity. Linares-Solano et al. [10] prepared platinum catalysts supported on a graphitized carbon black (V3G), which was subjected to various degrees of activation in air to increase the surface area. They observed that as the surface area of the parent sample increased from 62 m /g to 136 m /g,... 

Porous graphitic carbon is synthesized by a multistep chemical and thermal treatment from organic monomers deposited in the pores of a silica gel particle template and subsequently subjected to polymerization, carbonization, dissolution of the silica template and graphitization [170,172]. The silica gel template allows optimization of the adsorbent particle size, porosity and surface area for liquid chromatography. The selection of monomers and thermal treatment is responsible for the mechanical strength, high purity and absence of significant microporosity. Commercially available materials have particle sizes of 5 or 7 xm, a mean pore diameter of 25 nm and a surface area of 100-120 m /g. 

In addition to loss of the platinum, the carlxm support that anchors the platinum crystallites and provides electrical coimectivity to the gas-diffusion media and bipolar plates is also subject to degradation. In phosphoric acid fuel cell, graphitized carbons are the standard because of the need for corrosion resistance in high-temperature acid environments [129], but PEM fuel cells have not employed fully graphitized carbons in the catalyst layers, due in large part to the belief that the extra cost could be avoided. Electrochemical corrosion of carbon materials as catalyst supports will cause electrical isolation of the catalyst particles as they are separated from the support or lead to aggregation of catalyst particles, both of which result in a decrease in the electrochemical active surface area of the catalyst and an increase in the hydrophUicity of the surface, which can, in turn, result in a decrease in gas permeability as the pores become more likely to be filled with liquid water films that can hinder gas transport. 

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