Super-stabilization cations

Super-Stabilization of -Conjugated Cations by Annelation to Bicyclic Frameworks... 

Our success in super-stabilization of cation 6 led us to the preparation of a higher homologue, that is, cyclooctatetraene (COT), fully annelated with BCO units 9 (9). As compared with a large number of studies on its radical anion or dianions, the studies on the cationic species of COT have been quite limited. There have been only one study by Olah and Paquette on the substituted COT dication (70), which is a typical 6n Hiickel aromatic system, and few sporadic studies on radical cations, which involve indirect spectral observations, such as electronic spectra in Freon matrix at low temperature (77,72) and constant-flow ESR study (13). 

Neither methyl nor ethyl fluoride gave the corresponding cations when treated with SbFs. At low temperatures, methyl fluoride gave chiefly the methylated sulfur dioxide salt, (CH3OSO) ShF while ethyl fluoride rapidly formed the rert-butyl and ferf-hexyl cations by addition of the initially formed ethyl cation to ethylene molecules also formed ° At room temperature, methyl fluoride also gave the tert-butyl cation. In accord with the stability order, hydride ion is abstracted from alkanes by super acid most readily from tertiary and least readily from primary positions. 

Silver(I) /3-diketonate derivatives have received significant attention due to the ease with which they can be converted to the elemental metal by thermal decomposition techniques such as metal organic chemical vapor deposition (MOCVD).59 The larger cationic radius of silver(I) with respect to copper(I) has caused problems in achieving both good volatility and adequate stability of silver(I) complexes for the use in CVD apparatus. These problems have been overcome with the new techniques such as super critical fluid transport CVD (SFTCVD), aerosol-assisted CVD (AACVD), and spray pyrolysis, where the requirements for volatile precursors are less stringent. 

The study of the stabilizing effect of the nitrone group in cumyl radical (205) (Scheme 2.72) (362) and cumyl cation (206) (Scheme 2.73) (363) has shown that the nitrone group appears to be a super radical stabilizer and, at the same time, a weak cation stabilizer. ... 

The assumption that tertiary alkyl cations are not stable in solvents other than super-acids is widespread and was apparently well founded on many experiments by different workers over many years [20, 24]. For this reason the stability of our polymerised solutions was astonishing and it seemed at first unlikely that the cation of the electrolyte could be a simple tertiary ion the tert-butyl cation in the experiment with tert-butyl bromide and the ions 2-4 in the polymerised solutions. This was because we did not know then that Cesca,... 

R H) is much faster than alkylation, so that alkylation products are also derived from the new alkanes and carbocations formed in the exchange reaction. Furthermore, the carbo-cations present are subject to rearrangement (Chapter 18), giving rise to new carbocations. Products result from all the hydrocarbons and carbocations present in the system. As expected from their relative stabilities, secondary alkyl cations alkylate alkanes more Teadily than tertiary alkyl cations (the r-butyl cation does not alkylate methane or ethane). Stable primary alkyl cations are not available, but alkylation has been achieved with complexes formed between CH3F or C2H5F and SbFs-212 The mechanism of alkylation can be formulated (similar to that shown in hydrogen exchange with super acids, 2-1) as... 

Despite the seeming stability of 80, all attempts to prepare the cation as a stable species in super-acid media have been unsuccessful191 192. The retention of configuration at C(4) in solvolysis of cyclopentene derivatives suggests that there is some involvement of the... 

Cationic vinylidene complexes can be considered to be metal-stabilized vinyl cations in purely organic chemistry, vinyl cations can be obtained by dissociation of the super leaving group, TfO-, from the esters obtained from enolate anions and Tf20. 

This reaction proceeds as a conjugate process (see also Eq. 2, pathway B). It starts with ionization of 57 by action of super acid (HF/SbF5) to give f-butyl cation. Its further attack on TFE with formation of another cation 59, which is stabilized by adding fluoride anion, from either a counter anion or HF ... 

Alkyl cations like the tert-butyl cation (2) and 2-propyl cation (89) are significantly stabilized by hyperconjugative C-H and C-C a -back donation into the empty carbocationic p-orbitals. Protosolvation involving a -bonds can diminish this hyperconjugative stabilization and thus lead to super-electrophilic carbocationic species. 

With almost all of the conceivable coordination chemistry of the expanded porphyrins still left to be explored, it cannot be over-stres that the potential for new chemistry is enormous. This is i rticularly true when account is made of the fact that the chemistry of the metalloporphyrins has played a dominant role in modern inorganic chemistry. What with the possibility to enhance the stability of imusual coordination geometries (and, perhaps oxidations states) and the ability to form stable coordination complexes with a variety of unusual cations including those of the lanthanide and actinide series, the potential for new inorganic and organometallic discoveries are almost unlimited. For instance, as with the porphyrins, one may envision linear arrays of stacked expanded porphyrin macrocycles which may have unique conducting properties and/or which could display beneficial super- or semiconducting capabilities. Here, of course, the ability to coordinate not only to cations but also to anions could prove to be of tremendous utility. 

The methoxymethyl cation can be obtained as a stable sohd, MeOCHj SbF, Carbocations containing either a, p, or y silicon atom are also stabilized, relative to similar ions without the silicon atom. In super acid solution, ions such as CX (X = Cl, Br, I) have been prepared. Vinyl-stabilized halonium ions are also known. ... 

In the lithiation of fluoroanisoles (15) and (16) and their derivatives, butyllithium exclusively deprotonates the less acidic protons from the position ortho to the alkoxyl group. On the other hand, deprotonation takes place at the more acidic site, i.e. the ortho-position next to the fluorine substituent on reaction of the substrates with super bases, such as BuLi— t-BuOK or BuLi—N,N,N/,N//,N//-pentamethyldiethylenetriamine, in which lithium cation is stabilized by chelation in the combined base-system (Scheme 3.5) [ 14]. The lithium cation interacts preferentially with the more Lewis basic alkoxyl oxygen to locate butyllithium close to the position ortho to the alkoxyl group, enhancing kinetic deprotonation (see 17 in Scheme 3.5). 

Diels-Alder reactions. Compounds that give an oxygen-stabilized allyl cation are super-dienophiles in the presence of LiClQ,.OEt2. The method obviates the difficulties experienced with the low reactivities of 2-cyclohexenones. An intramolecular variant serves to construct tricyclic ketones expediently. 

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