Addition reactions hydride donors

In additions of hydride donors to a-chiral carbonyl compounds, whether Cram or anti-Cram selectivity, or Felkin-Anh or Cram chelate selectivity occurs is the result of kinetic control. The rate-determining step in either of these additions is the formation of a tetrahedral intermediate. It takes place irreversibly. The tetrahedral intermediate that is accessible via the most stable transition state is produced most rapidly. However, in contrast to what is found in many other considerations in this book, this intermediate does not represent a good transition state model for its formation reaction. The reason for this deviation is that it is produced in an... 

Addition of Hydride Donors and Organometallic Compounds to Carbonyl Compounds, Pages 305-3469 -Reaction of Ylides with Saturated or a,B-Unsaturated Carbonyl Compounds,... 

Krische et al. demonstrated intramolecular reaction with Co(dpm)2 (5mol%) and PhSiH3 (120 mol %) as a hydride donor (Scheme 8) [14-16]. Addition of aldehyde-enone 17 to a solution of the Co catalyst and phenylsi-lane resulted in the formation of the corresponding aldol cyclization product... 

Organometals and metal hydrides as electron donors in addition reactions 245 Oxidative cleavage of carbon-carbon and carbon-hydrogen bonds 253 Electron-transfer activation in cycloaddition reactions 264 Osmylation of arene donors 270... 

ORGANOMETALS AND METAL HYDRIDES AS ELECTRON DONORS IN ADDITION REACTIONS... 

Reactions of highly electron-rich organometalate salts (organocuprates, orga-noborates, Grignard reagents, etc.) and metal hydrides (trialkyltin hydride, triethylsilane, borohydrides, etc.) with cyano-substituted olefins, enones, ketones, carbocations, pyridinium cations, etc. are conventionally formulated as nucleophilic addition reactions. We illustrate the utility of donor/acceptor association and electron-transfer below. 

The reduced donor ability of the phosphinite complexes such as 5e and 5f has an impact beyond the catalyst activation stipulated above. Apparently, the decreased tendency to undergo oxidative addition reactions also disfavors catalyst deactivation via oxidative olefin addition. Accordingly, (vinyl) (hydride) complexes such as 3 are less relevant. Simultaneously, product oxidative addition is restricted and, as... 

In addition to the protonalion route, hydrido complexes may be prepared by reaction of carbonyl complexes with hydride donors ... 

The simple addition reaction in Scheme 19 illustrates how the notation is used. Ester (1) can be dissected into synthons (2), (3) and (4). Synthons for radical precursors (pro-radicals) possess radical sites ( ) A reagent that is an appropriate radical precursor for the cyclohexyl radical, such as cyclohexyl iodide, is the actual equivalent of synthon (2). By nature, alkene acceptors have one site that reacts with a radical ( ) and one adjacent radical site ( ) that is created upon addition of a radical. Ethyl acrylate is a reagent that is equivalent to synthon (3). Atom or group donors are represented as sites that react with radicals ( ) Tributyltin hydride is a reagent equivalent of (4). In practice, such analysis will usually focus on carbon-carbon bond forming reactions and the atom transfer step may be omitted in the notation for simplicity. 

Significantly better results in addition of non-stabilized nucleophiles have come from hydrogenolysis reactions using formate as a hydride donor as shown in Scheme 8E.46. The racemic cyclic acetate and prochiral linear carbonates were reduced in good enantioselectivities by monophosphine ligands (/ )-MOP (16) and (Zf)-MOP-phen (17), respectively [195]. The chirality of the allylsilane can be efficiently transferred to the carbinol center of the homoallylic alcohol by the subsequent Lewis acid catalyzed carbonyl addition reaction 1196], The analogous... 

In addition to their reactions with alkenes and carbanions as nucleophiles benzhydryl cations react with hydride donors.282 284 These hydride transfer reactions show the same linear dependence of log k upon E as the reactions with alkenes and the same constant relative selectivity, that is with slopes of plots close to 1.0, for structures ranging from cycloheptatriene to the... 

Because systematic variations in selectivity with reactivity are commonly quite mild for reactions of carbocations with n-nucleophiles, and practically absent for 71-nucleophiles or hydride donors, many nucleophiles can be characterized by constant N and s values. These are valuable in correlating and predicting reactivities toward benzhydryl cations, a wide structural variety of other electrophiles and, to a good approximation, substrates reacting by an Sn2 mechanism. There are certainly failures in extending these relationships to too wide a variation of carbocation and nucleophile structures, but there is a sufficient framework of regular behavior for the influence of additional factors such as steric effects to be rationally examined as deviations from the norm. Thus comparisons between benzhydryl and trityl cations reveal quite different steric effects for reactions with hydroxylic solvents and alkenes, or even with different halide ions... 

Fig. 6.40. On the chemo-selectivity of the reactions of hydride donors, organometallic compounds, and heteroatom-stabilized "carbanions with acylating agents (kM t refers to the rate constant of the addition of the nucleophile to the carboxyl carbon, and kadd2 refers to the rate constant of the addition of the nucleophile to the carbonyl carbon).

In Section 6.5 you learned that the acylations of hydride donors or of organometallic compounds, which give aldehydes or ketones, often are followed by an unavoidable second reaction the addition of the hydride or organometallic compound to the aldehyde or the ketone. In this chapter, we will study the intentional execution of such addition reactions. 

The addition of a hydride donor to an aldehyde or to a ketone gives an alcohol. This addition is therefore also a redox reaction, namely, the reduction of a carbonyl compound to an alcohol. Nevertheless, this type of reaction is discussed here and not in the redox chapter (Chapter 17). 

The so-called 1,4-addition (for the term see Figure 10.31) of hydride donors to a,j3-unsat-urated ketones yielding an enolate as the primary product and, after protic workup, a saturated ketone, is also known. A hydride donor that reduces unsaturated ketones in this manner is L-Selectride , which has been mentioned several times. An example of this type of reaction is given in the lower half of Figure 13.20. 

Other cyclic or bicyclic ketones do not have a convex side but only a less concave and a more concave side. Thus, a hydride donor can add to such a carbonyl group only from a concave side. Because of the steric hindrance, this normally results in a decrease in the reactivity. However, the addition of this hydride donor is still less disfavored when it takes place from the less concave (i.e., the less hindered) side. As shown in Figure 10.10 (top) by means of the comparison of two reductions of norbomanone, this effect is more noticeable for a bulky hydride donor such as L-Selectride than for a small hydride donor such as NaBH4. As can be seen from Figure 10.10 (bottom), the additions of all hydride donors to the norbomanone derivative B (camphor) take place with the opposite diastereoselectivity. As indicated for each substrate, the common selectivity-determining factor remains the principle that the reaction with hydride takes place preferentially from the less hindered side of the molecule. 

Fig. 10.11. Addition of various hydride donors to 4-tert-butylcyclohexanone. With L-Selectride the equatorial approach (Formula A) is preferred, with sterically (less) demanding hydride donors the reaction proceeds axially via transition state B (cf. text and, particularly. Side Note 10.1). For comparison see the Felkin-Anh transition state C (in Figure 10.16 EWG = electron-withdrawing group).

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