Allyl complexes from 1,3-dienes

Scheme 3-26 Fonnation of Tr-allyl complexes from 1,3-dienes and allenes.

The formation of 7r-allyl complexes from 1,3-dienes is very general.9 Its scope has hardly been explored yet. Its main potential lies in the ease of exchange of the substituent in the allylic ligand,10,11 and in the reversibility of the reaction leading to the complex.12... 

Transition metals promote formation of w-allyl complexes from dienes by nucleophilic attack. Different nucleophiles and dienes participate in the reaction, which may take two routes where the nucleophile and the metal add either from the same (path a) or the opposite face of the diene (path b). Nucleophiles may be divided into two classes one, which includes alcohols, amines, carboxylates and malonates, reacts preferentially according to (a) ... 

Cobalt, rhodium and iridium give rr-allyl complexes from dienes, e.g., the 7c-allyl complex XXXVIII from the cobalt hydride XXXVII ... 

Equations 3.64-3.66 illustrate routes to allyl complexes from dienes, diene complexes, and olefins. Allyl complexes have been prepared by the insertion of a conjugated diene into a metal hydride, alkyl, or acyl linkage, as illustrated for the cobalt complexes in Equation 3.64. ° Alternatively, allyl complexes have been prepared by nucleophilic or electrophilic attack on a coordinated diene. Equation 3.65 shows the formation of allyl complexes by the addition of carbanions to a cationic diene complex, and Equation 3.66 shows the formation of a cationic diene complex by the protonation of a neutral 1,3-diene complex. Allyl complexes have also been formed by the abstraction of an allylic proton from a metal-olefin complex, either by a base or by the metal itself. This reaction has been proposed as a step in the isomerization of olefins (Equation 3.67) and in the allylic oxidation of olefins (Equation 3.68). - ... 

PtMeL2] proceed in a Markownikov manner by electrophilic attack of Pf thus [Pt(A -2-methallyl)L2] is formed from allene and [PtMe-(acetone)L2], whereas the analogous 1,3-butadiene cation does not lead to a 7r-allylic derivative by Pt—Me insertion. The hydro cation, however, can react by either a Markownikov or an anti-Markownikov mechanism with either Pt+ or attack on the unsaturated ligand. This apparent versatility leads to the formation of Tr-allylic complexes from both allenes and 1,3-dienes with [PtHLg]. ... 

Among the iron triad metals most complexes are iron Tc-allyl adducts from dienes. This may be fortuitous or owing to an electronic property of the heavier elements. The ruthenium diene complex XXIXa shows no tendency to undergo insertion s, but the origin of this may be steric, as indicated by the protonation of (CO)3Ru(butadiene), which goes via complex XXIXb and yields XXXa S ... 

The interpretation of the early results is not obvious and in his review of 1980 (Ref. [4], pp. 84-103), Henry favored the 1,2-addition mechanism for all substrates. With the formation of the trany-acetoxy ir-allyl complex from acetoxylation of 1,4-cyclohexa-diene, clear evidence for the 1,2-addition process was later obtained (Scheme 14). 

If the unsaturated hydrocarbon is a diene, both double bonds may coordinate to palladium ). (Diene)palladium(II) complexes have been isolated and characterized. For example, 2 and 3 are stable complexes in which both double bonds are coordinated to the metal10. Conjugated dienes constitute a special case and although /j4-diene complexes, e.g. 4, are postulated as intermediates, they have not yet been isolated. The butadiene complex 4 is in equilibrium with the zr-allyl complex 5 in solution, and attempts to isolate the diene complex from this mixture lead to formation of a yellow crystalline complex 511. 

The stereochemistry of the dialkoxylation arises from two external attacks by the alcohol, one on the rr-diene complex and the second on the intermediate jr-allyl complex. This is in accordance with the other palladium-catalyzed 1,4-syn additions discussed above. 

The fact that organosamarium allyl complexes of the type Cp 2Sm(CH2CH=CHR) can arise from the treatment of Cp 2Sm or [Cp 2Sm(/r-H)]2 with a variety of olefin and diene substrates makes samarium chemistry more intriguing. The reaction modes are illustrated in Scheme 18. These allylsamarium complexes 55 react with C02 to afford the carboxylate products 56, which participate in monometallic/bimetallic interconversions (Equation (10)). Carbon disulfide and 0=C=S also insert into carbon-samarium bonds, which form only monometallic species.29... 

Other conjugated diene systems readily react with either H4Ru4-(CO)i2 or Ru3(CO)i2, to yield 7r-allyl complexes. Thus, butadiene yields the crotyl derivative HRu3(CO)9C4H5. The X-ray structure of the related adduct formed from cis-trans- or trans-trans-2,4-diene is shown in Fig. 12. The hydride is considered to bond to the Ru(l)-Ru(2) edge, as this is the longest metal-metal bond in the structure and in the... 

When, furthermore, phenols (368) are coupled with 1 in the presence of a Pd° catalyst, the phenoxy-methyl-1,3-dienes 369 are produced [158]. As aryl allyl ethers, these can be made to undergo a Claisen rearrangement (205 °C, DMF) and the ensuing 2-(l,3-dienylmethyl)phenols 370 finally cydize in the presence of a trace of acid to a mixture of exo-methylene chromans 371 (major product) and dihydrobenzofur-ans 372 - a remarkable generation of functional and structural complexity from simple starting materials with 100% atom economy and underlining impressively the synthetic versatility of modern allene chemistry ... 

Liebeskind and coworkers have examined the reactivity of (2//-pyran)Mo(CO)2Cp+ cations 210, which may be prepared in optically active form from carbohydrate precursors. Nucleophilic attack on cation 210 occurs at the diene terminus bonded to the ring oxygen to give jr-allyl complexes 51 (Scheme 53)85. Hydride abstraction from 51 gives the cation 54 addition of a second nucleophilie occurs regioselectively to give... 

Ruthenium complexes B also undergo fast reaction with terminal alkenes, but only slow or no reaction with internal alkenes. Sterically demanding olefins such as, e.g., 3,3-dimethyl-l-butene, or conjugated or cumulated dienes cannot be metathesized with complexes B. These catalysts generally have a higher tendency to form cyclic oligomers from dienes than do molybdenum-based catalysts. With enol ethers and enamines irreversible formation of catalytically inactive complexes occurs [582] (see Section 2.1.9). Isomerization of allyl ethers to enol ethers has been observed with complexes B [582]. 

One may inquire whether the evidence that 77-allyl complexes yield desorbed olefins when formed from dienes and hydrogen, or from alkenes, is pertinent to the question concerning the course of the exchange of such complexes formed by the adsorption of saturated hydrocarbons. The composition of the surface must be different under the two circumstances in one there must be few sites not occupied by olefin or half-hydrogenated intermediates, while in the other (the exchange of saturated hydrocarbons) many sites must be vacant. Consequently, in the absence of an excess of any unsaturated hydrocarbon, there is no driving force for the desorption (or displacement) of the unsaturated intermediates which are formed on the surface and intermediates of any degree of unsaturation remain bonded to the surface and leave it only as saturated hydrocarbon. Yet the evidence obtained from the reactions of the unsaturated hydrocarbons must indicate the paths which may be traversed under either circumstance. 

The insertion of CO into 7r-allylpalladium complexes has been used to prepare various P/y-unsaturated carboxylic acid derivatives. The process can be initiated from preformed allyl complexes,227-235 catalyti-cally from appropriate ir-allyl precursors228,229 236 237 or from diene-Pd complexes.238 239 Particularly mild conditions, involving low pressures and temperatures, to accomplish this insertion have been discovered.235 The key reagent in allowing these mild conditions to be employed was found to be carboxy-late anions.235 For unsymmetrical allyl complexes, CO insertion occurs preferentially at the less-substituted allyl terminus (equations 71-73). 

The complementary approach, activation of unsaturated hydrocarbons toward electrophilic attack by complexation with electron-rich metal fragments, has seen limited investigation. Although there are certainly opportunities in this area which have not been exploited, the electrophilic reactions present a more complex problem relative to nucleophilic addition. For example, consider the nucleophilic versus electrophilic addition to a terminal carbon of a saturated 18-electron metal-diene complex. Nucleophilic addition generates a stable 18-electron saturated ir-allyl complex. In contrast, electrophilic addition at carbon results in removal of two valence electrons from the metal and formation of an unstable ir-allyl unsaturated 16-electron complex (Scheme 1). 

Both stoichiometric and catalytic reactions involving 7r-allylpalladium complexes are known. Reactions involving 7r-allylpalladium complexes become stoichiometric or catalytic depending on the preparative methods of the 7r-allylpalladium complex. Preparation of the 7r-allylpalladium complexes 6 by the oxidative addition of various allylic compounds 5, mainly esters to Pd(0), and their reactions with nucleophiles are catalytic. This is because Pd(0) is regenerated after the reaction with the nucleophile, and the Pd(0) reacts again with allylic compounds to form the complex 6. These catalytic reactions are treated in Section 4.3. However, the preparation of 7r-allyl complexes 6 from alkenes 7 requires Pd(II) salts. Subsequent reaction with nucleophiles generates Pd(0). As a whole, Pd(II) is consumed, and the reaction ends as the stoichiometric process, because in situ reoxidation of Pd(0) to Pd(II) is not attainable in this case. Also, 7i-allylpalladium complex 9 is formed by the reaction of conjugated dienes 8 with Pd(II), and the reaction of 9 with nucleophiles is stoichiometric. 

Ene-type products are obtained by Co- and Fe-catalysed reaction of dienynes. Cocatalysed cyclization of substrate 111 proceeds smoothly with respect to the diene, acetylene and allylic ether moiety to afford 114. In this cyclization, the 7i-allyl complex 112 is formed by insertion of the diene to Co—H, followed by domino insertions of the triple and double bonds to give 113. The final step is the elimination of the /J-alkoxidc group from 113 to form 114 [47], The six-membered ene-type products 117 and 118 are obtained from the reaction of 115 catalysed by an Fe bipyridyl complex. The reaction seems to involve oxidative cyclization to form 116. Subsequent -elimination and reductive elimination provide 117 and 118. As another possibility, insertion of the diene to Fe—H gives a 7i-allyl complex. Then double bond insertion and -elimination should give 117 and 118 [48],... 

Friedel Crafts acetylation of butadiene complex 56 proceeds smoothly to give a mixture of 1-acetyldienes 58 and 59 via the cationic 7r-allyl complex 57 [16]. Intramolecular Friedel-Crafts acylation with the acid chloride of the diene complex 60, promoted by deactivated AICI3 at 0 °C, gave the cyclopentanones. The (Z)-dienone complex 61 was the major product and the ( )-dienone 62 the minor one [17]. Acetylation of the 1,3-cyclohexadiene phosphine complex 63 proceeded easily at —78°C to give the rearranged complex 65 in 85% yield. Without phosphine coordination, poor results were obtained [18,19], In this reaction, the acetyl group at first coordinates to Fe, and attacks at the terminal carbon of the diene from the same... 

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