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Other Ionic Reactions

Three new experimental techniques, developed within the past decades, now make it possible to study ionic reactions in the gas phase as well. These are pulsed ion-cyclotron-resonance (ICR) mass spectrometry, pulsed high-pressure mass spectrometry (HPMS), and the flowing afterglow (FA) technique [469-478 see also the references given in Section 4.2.2]. Although their approaches are quite independent, the results obtained for acid/base and other ionic reactions agree within an experimental error of 0.4... 1.3 kJ/mol (0.1... 0.3 kcal/mol) and are considered as reliable as those obtained in solution. [Pg.147]

The arguments used here for Sn2 displacement reactions can be generally applied to other ionic reactions. [Pg.159]

As in case of other ionic reactions, onium ions in the polymerization of heterocycles can exist in various forms of ionic ag tes, as paired or free ions, etc. [Pg.53]

As with all living polymerizations, the formation of bloek eopolymers is possible if the active chain end of one polymer block can initiate the polymerization of a second monomer. This may mean that when block copolymers are prepared, the sequence of monomer addition may be critical. In this respect, the CRP techniques are no different from the other ionic reactions, but they do have one specific advantage. Because many of the CRP processes do not reach 100% conversion, it is best to separate and purify the polymer adduct formed in the first step, which can then be stored and used as a macroirfitiator for the growth of the second block, with no loss of activity. The use of such a macroinitiator helps to control the subsequent reaction more effectively and produces products with very low polydispersities, because for the macroinitiator, diffusion and reactivity are decreased, thereby mininuzing radical-radical coupling. [Pg.142]

Among other possible reactions, these free radicals can initiate ordinary free-radical polymerization. The Ziegler-Natta systems are thus seen to encompass several mechanisms for the initiation of polymerization. Neither ionic nor free-radical mechanisms account for stereoregularity, however, so we must look further for the mechanism whereby the Ziegler-Natta systems produce this interesting effect. [Pg.489]

Chemical Properties. Higher a-olefins are exceedingly reactive because their double bond provides the reactive site for catalytic activation as well as numerous radical and ionic reactions. These olefins also participate in additional reactions, such as oxidations, hydrogenation, double-bond isomerization, complex formation with transition-metal derivatives, polymerization, and copolymerization with other olefins in the presence of Ziegler-Natta, metallocene, and cationic catalysts. All olefins readily form peroxides by exposure to air. [Pg.426]

Liquid-phase chlorination of butadiene in hydroxyhc or other polar solvents can be quite compHcated in kinetics and lead to extensive formation of by-products that involve the solvent. In nonpolar solvents the reaction can be either free radical or polar in nature (20). The free-radical process results in excessive losses to tetrachlorobutanes if near-stoichiometric ratios of reactants ate used or polymer if excess of butadiene is used. The "ionic" reaction, if a small amount of air is used to inhibit free radicals, can be quite slow in a highly purified system but is accelerated by small traces of practically any polar impurity. Pyridine, dipolar aptotic solvents, and oil-soluble ammonium chlorides have been used to improve the reaction (21). As a commercial process, the use of a solvent requites that the products must be separated from solvent as well as from each other and the excess butadiene which is used, but high yields of the desired products can be obtained without formation of polymer at higher butadiene to chlorine ratio. [Pg.38]

Pourbaix diagrams are only thermodynamic predictions and yield no information about the kinetics of the reactions involved nor are the influences of other ionic species which may be present in the solution included. Complexing ions, particularly haUdes, can interfere with passivation and can influence... [Pg.276]

Other Ionic Impurities from Incomplete Metathesis Reactions... [Pg.26]

Apart from halide and protic impurities, ionic liquids can also be contaminated with other ionic impurities from the metathesis reaction. This is especially likely if the alkali salt used in the metathesis reaction shows significant solubility in the... [Pg.26]

The previous sections show that certain ionic liquids, namely the chloroalumi-nate(III) ionic liquids, are capable of acting both as catalyst and as solvent for the polymerization of certain olefins, although in a somewhat uncontrolled manner, and that other ionic liquids, namely the non-chloroaluminate(III) ionic liquids, are capable of acting as solvents for free radical polymerization processes. In attempts to carry out polymerization reactions in a more controlled manner, several studies have used dissolved transition metal catalysts in ambient-temperature ionic liquids and have investigated the compatibility of the catalyst towards a range of polymerization systems. [Pg.326]

TTigh pressure mass spectrometry has recently provided much detailed kinetic data (5, 12, 13, 14, 15, 17, 22, 24, 26, 29) concerning ionic reactions heretofore unobtainable by other means. This information has led to increased understanding of primary reaction processes and the fate of ionic intermediates formed in these processes but under conditions distinctly different from those which prevail in irradiated gases near room temperature and near atmospheric pressure. Conclusive identification and measurements of the rate constants of ionic reactions under the latter conditions remain as both significant and formidable problems. [Pg.284]

Ionic Reactions in TD/D2 Ethane Mixtures. The data in Table III show that deuteron transfer occurs in irradiated mixtures of D2 and ethane as well. Data are shown only for temperatures (<25°C.) at which ionic reactions clearly predominate. Analysis of data concerning thermal atomic and free-radical reactions at higher temperatures will be published elsewhere in the near future. The reaction of D3 + with ethane has been observed directly (1) and postulated (2) by other workers. Both groups have proposed that the sequence initiated by deuteron transfer to ethane proceeds as follows ... [Pg.292]

These reactions proceed without solvent as well (Reaction 29)7 On the other hand, reaction in the presence of AICI3 in CH2CI2 gave exclusively gem-disubstituted olefins (Reaction 30)7 The presence of Lewis acid shifts the reaction mechanism from radical to ionic, affording a complementary regios-electivity. [Pg.132]

When the layer has electronic in addition to ionic conductivity, the electrochemical reaction will be partly or completely pushed out to its outer surface. In addition, other electrochemical reactions involving the solution components, particularly anodic oxygen evolution, can occur on top of the layer. [Pg.304]

It was G. N. Lewis who extended the definitions of acids and bases still further, the underlying concept being derived from the electronic theory of valence. It provided a much broader definition of acids and bases than that provided by the Lowry-Bronsted concept, as it furnished explanations not in terms of ionic reactions but in terms of bond formation. According to this theory, an acid is any species that is capable of accepting a pair of electrons to establish a coordinate bond, whilst a base is any species capable of donating a pair of electrons to form such a coordinate bond. A Lewis acid is an electron pair acceptor, while a Lewis base is an electron pair donor. These definitions of acids and bases fit the Lowry-Bronsted and Arrhenius theories, and cover many other substances which could not be classified as acids or bases in terms of proton transfer. [Pg.592]

SRV1 reactions of gem-halonitroalkanes with the anion of active methylene compounds followed by deethoxycarbonylation and denitration provide useful methods for preparing highly substituted olefins, as shown in Eq. 7.140.186 Because the SRN I reaction is less sensitive to steric effects than the ionic reaction, such reaction as that shown in Eq. 7.140 has merits over other... [Pg.224]

Additions of the Reformatsky-type reagents to aldehydes can also proceed in ionic solvents (Scheme 108).287 Three ionic liquids have been tested 8-ethyl-l,8-diazbicyclo[5,4,0]-7-undecenium trifluoromethanesulfonate ([EtDBU][OTf]), [bmim][BF4], and [bmim][PF6]. The reactions in the first solvent provided higher yields of alcohols 194 (up to 93%), although results obtained for two other ionic liquids were also comparable with those reported for conventional solvents. [Pg.387]

The overall distribution of lanthanides in bone may be influenced by the reactions between trivalent cations and bone surfaces. Bone surfaces accumulate many poorly utilized or excreted cations present in the circulation. The mechanisms of accumulation in bone may include reactions with bone mineral such as adsorption, ion exchange, and ionic bond formation (Neuman and Neuman, 1958) as well as the formation of complexes with proteins or other organic bone constituents (Taylor, 1972). The uptake of lanthanides and actinides by bone mineral appears to be independent of the ionic radius. Taylor et al. (1971) have shown that the in vitro uptakes on powdered bone ash of 241Am(III) (ionic radius 0.98 A) and of 239Pu(IV) (ionic radius 0.90 A) were 0.97 0.016 and 0.98 0.007, respectively. In vitro experiments by Foreman (1962) suggested that Pu(IV) accumulated on powdered bone or bone ash by adsorption, a relatively nonspecific reaction. On the other hand, reactions with organic bone constituents appear to depend on ionic radius. The complexes of the smaller Pu(IV) ion and any of the organic bone constituents tested thus far were more stable (as determined by gel filtration) than the complexes with Am(III) or Cm(III) (Taylor, 1972). [Pg.41]

It is clear that reactions suitable for use in titrimetric procedures must be stoichiometric and must be fast if a titration is to be carried out smoothly and quickly. Generally speaking, ionic reactions do proceed rapidly and present few problems. On the other hand, reactions involving covalent bond formation or rupture are frequently much slower and a variety of practical procedures are used to overcome this difficulty. The most obvious ways of driving a reaction to completion quickly are to heat the solution, to use a catalyst, or to add an excess of the reagent. In the last case, a hack titration of the excess reagent will be used to locate the stoichiometric point for the primary reaction. Reactions employed in titrimetry may be classified as acid-base oxidation-reduction complexation substitution precipitation. [Pg.192]

See other pages where Other Ionic Reactions is mentioned: [Pg.96]    [Pg.149]    [Pg.37]    [Pg.233]    [Pg.265]    [Pg.149]    [Pg.96]    [Pg.149]    [Pg.37]    [Pg.233]    [Pg.265]    [Pg.149]    [Pg.293]    [Pg.72]    [Pg.574]    [Pg.214]    [Pg.509]    [Pg.509]    [Pg.509]    [Pg.509]    [Pg.509]    [Pg.509]    [Pg.341]    [Pg.246]    [Pg.175]    [Pg.155]    [Pg.583]    [Pg.21]    [Pg.85]    [Pg.222]    [Pg.95]    [Pg.241]    [Pg.6]    [Pg.47]    [Pg.73]   


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Ionic reactions

Other Ionic Impurities from Incomplete Metathesis Reactions

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