Lithium kinetic aspects

SOME THERMODYNAMICS AND KINETICS ASPECTS OF THE GRAPHITE-LITHIUM NEGATIVE ELECTRODE FOR LITHIUM-ION BATTERIES... 

In previous chapters the influence of the gegenion and the solvent on rearrangements of carbanions mostly concerned the rate of a certain reaction (and thus kinetic aspects), as, e.g., in the case of the cyclopropyl-allyl anion rearrangement (Sect. 2.1), the ally anion isomerization (Sect. 2.2), the cyclization of 5-hexenyl alkali metal compounds (Sect. 4) or the configurational isomerization of a-substituted vinyl-lithium compounds (Sect. 5). 

Earlier studies had demonstrated that such enolates would participate in aldol condensations with aldehydes however, the stereochemical aspects of the reaction were not investigated (68). For the cases summarized in Table 25, the zirconium enolates were prepared from the corresponding lithium enolates (eq. [54]). Control experiments indicated that no alteration in enolate geometry accompanies this ligand exchange process, and that the product ratio is kinetically controlled (35). From the cases illustrated, both ( )-enolates (entries A-E) and (Z)-enolates (entries F-H) exhibit predominant kinetic erythro diastereoselection. Although a detailed explanation of these observations is clearly speculative, certain aspects of a probable... 

In 1998, Hasanayn and Streitwieser reported the kinetics and isotope effects of the Aldol-Tishchenko reaction . They studied the reaction between lithium enolates of isobu-tyrophenone and two molecule of beuzaldehyde, which results iu the formation of a 1,3-diol monoester after protonation (Figure 28). They analyzed several aspects of this mechanism experimentally. Ab initio molecular orbital calculatious ou models are used to study the equilibrium and transition state structures. The spectroscopic properties of the lithium enolate of p-(phenylsulfonyl) isobutyrophenone (LiSIBP) have allowed kinetic study of the reaction. The computed equilibrium and transition state structures for the compounds in the sequence of reactions in Figure 28 are given along with the computed reaction barriers and energy in Figure 29 and Table 6. 

Rhodium-catalyzed carbonylation of methanol is known as the Monsanto process, which has been studied extensively. From the reaction mechanism aspect, the study of kinetics has proved that the oxidative addition of methyl iodide to the [Rh(CO)2l2] is the rate-determining step of the catalytic cycle. It was also observed that acetyl iodide readily adds to [Rh(CO)2l2], indicating that the acetyl iodide must be scavenged by hydrolysis in order to drive the overall catalytic reaction forward. An alternative to sequential reductive elimination and the hydrolysis of acetyl iodide is the nucleophilic attack of water on the Rh acetyl complex and the production of acetic acid. The relative importance of these two alternative pathways has not yet been fully determined, although the catalytic mechanism is normally depicted as proceeding via the reductive elimination of acetyl iodide from the rhodium center. The addition of iodide salts, especially lithium iodide, can realize the reaction run at lower water concentrations thus, byproduct formation via the water gas shift reaction is reduced, subsequently improving raw materials consumption and reducing downstream separation. In addition to the experimental studies of the catalytic mechanism, theoretical studies have also been carried out to understand the reaction mechanism [17-20]. 

There are a large variety of carbonaceous materials that can interact with lithium ions in solutions and serve as Li insertion anodes in Li-ion batteries. The behavior of the lithium insertion processes into carbons in terms of capacity, stability, kinetics, and potential profile, depends very strongly on their 3D structure and morphology. Indeed, this chapter deals with the surface chemistry of electrodes, and hence, cannot deal in depth with structural aspects of carbonaceous materials. However, it was found and clearly demonstrated that the surface chemistry of carbons, and especially their surface film related stability, depends very strongly on their 3D structure. Therefore, in this section we deal with some structural aspects of carbonaceous materials. 

---