Proton reactions with fluoride

All the rearranged products derived from (12) and (15) have been rationalized as arising by proton loss or reaction with fluoride ion of the respective homoallylic C-19 cations. The structures of the cations derived from (15) are represented by structures (20) to (24)." ... 

Electronegatively substituted acetylenes, such as dimethyl acetylenedicar-boxylate, do not react under normal conditions but will add the elements of hydrogen fluoride by reaction with fluoride ion (e g, CsF or tetraalkylammonium dihydrogen trifluoride) and a proton source under phase-transfer conditions [49, 50] (equation 8)... 

The potentiometric experiments used the method of competing reactions with fluoride and changes in activity coefficients between the media used being determined using Th which does not hydrolyse in the proton concentration range examined. The stabil-... 

In entry 5 [35], the isolation of glycosyl fluoride 36 (15% yield). [Its formation was assumed to have involved elimination, stereoselective fluoride attack at C-5 and protonation. An alternative mechanism may consist of hydride shift (MS[4,H-5]) and reaction, with fluoride, of the intermediate oxocarbe-nium ion to form the more stable anomer.]... 

With very electrophilic olefins, an alternative hydrogen fluoride addition process is often preferred This process, involving reaction of the olefin with fluoride ion in the presence of a proton donor, is applicable to certain perhalogen ated alkenes [/] and substrates with other electron attracting groups attached to the double bond [i5, 36] (equations 4 and 5)... 

Only a few examples exist describing the products from the allenylic/propargylic carbanion resulting from the deprotonation of 18 and reaction with other electrophiles instead of protons which lead to products analogous to 19 [48]. Thus, treating the propargyl compound 21 with tetrabutylammonium fluoride (TBAF) in the presence of benzaldehyde furnishes the C,C-connected compound 22 [41]. 

In this procedure, the ketone is first converted to its enol acetate by reaction with acetic anhydride in the presence of a proton acid. Since this enol acetylation is performed under equilibrating conditions, the more stable enol acetate (usually the more highly substituted isomer) is produced. Acetylation of this enol acetate, catalyzed by the Lewis acid boron trifluoride, usually leads to the formation of the enol acetate of a /3-diketone which is cleaved by boron trifluoride to form acetyl fluoride and the borofluoride complex of the /3-diketone. Thus, this procedure offers a convenient and general synthetic route... 

An early report (Briscese and Riveros, 1975) revealed that in the gas phase, alkoxide ions can displace fluoride from fluorobenzene (91). Hydroxide ion fails to react because C6H5F is more acidic than H20 and thus proton transfer becomes the most important channel. Similar reactions with other monohalobenzenes are complicated because these substrates usually generate halide ions directly by dissociative electron attachment. 

The first long-lived fluorine-containing carbocation was discovered by Olah and coworkers.32 Thus, the fluorodimethylcarbcnium ion [Me2CF+] was obtained by protonation of 2-fluoropropene and also from 2,2-difluoropropane by reaction with antimony(V) fluoride. In the course of these investigations it was found that a-F stabilizes a cationic state, whereas fi-F is destabilizing. Attempts to prepare the simplest member of this class, the trifluoromethyl carbocation CF3+ failed. The ionization of trifluoromethyl halides with antimony(V) fluoride at — 80 C yielded only carbon tetrafluoride. 

Af,Ar,AOV -Tetramethylnaphthalene-l,8-diamine described as Proton Sponge 38 (see Section 1.2) has the ability to act as a fluoride ion donor when its hydrofluoridc is used. Furthermore, it may be used to promote oligomerization reactions of fluorinated alkenes, e.g. 3, and poly-fluoroalkylation reactions with activated perfluoroaromatic compounds, e.g. 4.38... 

Alkoxyxenon fluorides (ROXeF), generated from XeF2 on reaction with alcohols, react with indene as positive oxygen electrophiles when BF3.Et20 is used as catalyst. By contrast, with proton catalysts they react as apparent fluorine electrophiles87. 

Fluorinated -alkenes and -cycloalkenes have a special relationship with their hydrocarbon analogues, usually exhibiting a chemistry that is complementary. For example, the fluorinated systems are frequently susceptible to nucleophilic attack, in some cases dramatically so, and therefore reactions of nucleophiles with fluorinated alkenes often reveal unique new chemistry. This chapter covers electrochemical reduction, principles governing orientation and reactivity of fluorinated alkenes towards nucleophiles, fluoride ion as a nucleophile and the mirror-image relationship of this chemistry with that of proton-induced reactions, reactions with nitrogen-, oxygen-, carbon- centred nucleophiles etc., and, finally, chemistry of some oligomers of fluorinated -alkenes and -cycloalkenes. 

The protonated aluminol sites are the most effective fluoride sorption sites and are usually responsible for the rapid kinetics due to coulombic attraction between the positively charged sites and the negatively charged fluoride species. The reaction with non-protonated sites involves ligand exchange, leads also to the formation of inner-sphere complexes, releases hydroxyl ions, is slow and characterized by a higher activation energy. 

The 5 -0-tosyl derivative of cytidine 227, upon reaction with KF and an azocrown ether, gave, unexpectedly, instead of the nucleophilic substitution product, the oxazocine 228 via nucleophilic attack by the 2-carbonyl oxygen initiated by proton abstraction from N-4 by fluoride (Scheme 46) <1998BML1317>. 

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