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Graphite intercalation compounds GICs

Using dilatometry in parallel with cyclic voltammetry (CV) measurements in lmolL 1 LiC104 EC-l,2-dimethoxy-ethane (DME), Besenhard et al. [87] found that over the voltage range of about 0.8-0.3 V (vs. Li/Li+), the HOPG crystal expands by up to 150 percent. Some of this expansion seems to be reversible, as up to 50 percent contraction due to partial deintercalation of solvated lithium cations was observed on the return step of the CV. It was concluded [87] that film formation occurs via chemical reduction of a solvated graphite intercalation compound (GIC) and that the permselective film (SEI) in fact penetrates into the bulk of the HOPG. It is important to repeat the tests conducted by Besenhard et al. [87] in other EC-based electrolytes in order to determine the severity of this phenomenon. [Pg.435]

B. Halogenation in Presence of Activated Carbon and Graphite Intercalation Compounds (GIC)... [Pg.542]

Carbon atoms crystallize in several forms. Graphite and diamond are well known carbon polymorphs. Fullerenes, which were discovered in the 1980 s, have also been well characterized. Carbon materials show a variety of different physical and chemical properties. Because of this the electronic structure of carbon materials has been investigated using a number of different experimental techniques, for example, XPS, UPS and XANES. Theoretical studies of carbon materials have been also performed. However, experimentally observed spectra are not always consistent with theoretical predictions. Recently, in order to understand the various kinds of observed electronic spectra, DV-Xa calculations have been performed on a small cluster model. [1] In the present paper, we report results of DV-Xa calculations performed on the carbon materials graphite, alkali graphite intercalation compounds (GIC), fullerene, and fluorinated fullerenes. [Pg.302]

Figure 9.37 Raman spectra of graphite and graphite intercalation compounds (GIC) with FeCl3. A lower stage number indicates a higher degree of intercalation. Figure 9.37 Raman spectra of graphite and graphite intercalation compounds (GIC) with FeCl3. A lower stage number indicates a higher degree of intercalation.
C0CI2 in a graphite intercalation compound (GIC) CoCl2-2H20... [Pg.218]


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Compounds intercalation compound

Graphite compounds

Graphite intercalate

Graphite intercalates

Graphite intercalation

Graphite intercalation compound

Graphitic compounds

Intercalated graphite

Intercalating compounds

Intercalation compounds

Intercallation compounds

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