Palladium-catalyzed reactions reductive elimination

Intramolecular arylation of G-H bonds gives cyclic aromatic compounds. In this intramolecular arylation, the carbon-palladium cr-bond is first formed by the oxidative addition of Pd(0) species and then the resulting electrophilic Pd(n) species undergoes the intramolecular G-H bond activation leading to the formation of the palladacycle, which finally affords the cyclic aromatic compounds via reductive elimination.87 For example, the fluoroanthene derivative is formed by the palladium-catalyzed reaction of the binaphthyl triflate, as shown in Scheme 8.88 This type of intramolecular arylation is applied to the construction of five- and six-membered carbocyclic and heterocyclic systems.89 89 89 ... 

Disubstituted silole derivatives are synthesized by the palladium-catalyzed reaction of (trialkylstannyl)di-methylsilane with terminal alkynes (Equation (107)).266 The mechanism is supposed to involve a palladium silylene complex, which is generated via /3-hydride elimination from LJ3d(SiMe2H)(SnBu3) (Scheme 62). Successive incorporation of two alkyne molecules into the complex followed by reductive elimination gives rise to the silole products. 

Palladium-catalyzed reaction of a 3,4-allenol with iodobenzene proceeds through an oxypalladation-reductive elimination sequence to give a 2,3-dihydrofuran efficiently (Scheme 16.8) [13,14],... 

On the other hand, the use of [Rh(CO)2Cl]2 as a catalyst results in ring opening of the siloxycyclopropanes 13 to the silyl enol ethers 14 with high stereoselectivity [10]. The 2-siloxyrhodacyclobutane 15a is proposed to undergo j8-elimination to give jr-allylrhodium 16a followed by reductive elimination to the silyl enol ether 14a. 1-Trimethylsiloxybicyclo[n.l.0]alkanes serve as / -metallo-carbonyl compounds via desilylation with a variety of transition metals [11]. The palladium-catalyzed reaction of the siloxycyclopropanes 17 under carbon monoxide in chloroform provides a route to the 4-keto pimelates 18. In the presence of aryl triflates, the 1,4-dicarbonyl compounds 19 are... 

The palladium-catalyzed reaction of aryl- and vinyl-tin reagents with stereochemically defined allyl chlorides proceeds with overall retention of configuration, indicating that the second step, entailing interaction of the iT-allylpalladium complex and the organotin, proceeds by transmetallation and reductive elimination (attack at Pd, retention) (equations 166 and 167).142145 Comparable results were obtained with cyclic vinyl epoxides and aryltins.143... 

In spite of the successful use of NHCs in a number of palladium-catalyzed reactions, no system for hydrogenation was reported until 2005. This can be easily explained as it had been observed that hydridopalladium-carbene species decompose due to attack of the hydride on the carbene, which results in its reductive elimination to yield the corresponding imidazolium salt [ 190]. However, Cavell and co-workers recently showed that the oxidative addition of imidazolium salts to bis-carbenic palladium complexes leads to isolable NHC-hydridopalladium complexes [191]. This elegant work evidenced the remarkable stabilizing effect of NHC ligands in otherwise reactive species and led to the development of the first NHC-palladium catalyst for hydrogenation. 

Bulky ligands as above have also proved to be effective in other palladium-catalyzed reactions of aryl halides, e.g., amination [16-19], Suzuki-Miyaura reaction [20-22], Mizoroki-Heck reaction [23, 24], Migita-Kosugi-Stille reaction [25], and aryloxylation and alkoxylation [26-28] as well as the reaction with various carbon nucleophiles as described below. The ligands are considered to enhance both the initial oxidative addition of aryl halides and the reductive elimination of products [29, 30]. The effectiveness of the commercially available simple ligand, P(f-Bu)3, was first described for the amination by Nishiyama et al. [16]. 

The numerous palladium-catalyzed organic reactions have a relatively small number of elementary steps. Oxidative Addition, Reductive Elimination, ligand coordination, and addition to coordinated ligands (either intramolecular or intermolecu-lar) are the most important classes of transformations in most palladium catalytic cycles. The exact nature of the species within the coordination sphere of palladium and the order in which the steps take place are responsible for the variety of the organic products produced. Four representative and important palladium-catalyzed reactions are briefly discussed here to illustrate the range of organopalladium reactions. 

As already mentioned for rhodium carbene complexes, proof of the existence of electrophilic metal carbenoids relies on indirect evidence, and insight into the nature of intermediates is obtained mostly through reactivity-selectivity relationships and/or comparison with stable Fischer-type metal carbene complexes. A particularly puzzling point is the relevance of metallacyclobutanes as intermediates in cyclopropane formation. The subject is still a matter of debate in the literature. Even if some metallacyclobutanes have been shown to yield cyclopropanes by reductive elimination [15], the intermediacy of metallacyclobutanes in carbene transfer reactions is in most cases borne out neither by direct observation nor by clear-cut mechanistic studies and such a reaction pathway is probably not a general one. Formation of a metallacyclobu-tane requires coordination both of the olefin and of the carbene to the metal center. In many cases, all available evidence points to direct reaction of the metal carbenes with alkenes without prior olefin coordination. Further, it has been proposed that, at least in the context of rhodium carbenoid insertions into C-H bonds, partial release of free carbenes from metal carbene complexes occurs [16]. Of course this does not exclude the possibility that metallacyclobutanes play a pivotal role in some catalyst systems, especially in copper-and palladium-catalyzed reactions. 

Preparation of the lactone fragment started with a mixture of (2 ,45) and (25,4S)-4-methyl-2-phenylsulfenyl-y-butyrolactone (53) which was alkylated with ( )-l,9-diiodo-l-nonene. The corresponding iodo compound 100 so obtained was then coupled with the alkyne 99 through the efficient palladium catalyzed reaction (Pd(PPh3)4, Cul, Et3N, room temperature) in 86 % yield. Enyne reduction of 101 with Wilkinson s catalyst, then oxidation of the sulfide into sulfoxide and subsequent thermal elimination gave rise to the title compound 90. The synthesis was achieved in 20 steps and in 0.36 % yield. 

Path (b) is the direct path, simply taking place from a four-coordinate, 16-electron complex. Many intermediates presumed in palladium-catalyzed reactions are considered to follow this path. On the other hand, in path (c), reductive elimination is induced by association with external ligands such as olefins and phosphines. This path has been observed mainly for nickel complexes. 

Palladium-Catalyzed Reactions Involving Reductive Elimination... 

The implications of tins equation are detailed later in the context of the basic three-step catalytic cycle for palladium-catalyzed cross-couphng reactions [llf involving (i) oxidative insertion of palladium(O) into an alkyl hahde (ii) transmetallation of the transferable group from the donor moiety onto palladium and (iii) reductive elimination of the resultant organopaUadium species to give the coupled product and regenerate the palladium(O) catalyst... 

The Suzuki Coupling (Section 24.5B) The Suzuki coupling reaction is a palladium-catalyzed reaction of an organoboron compound with an organic halide or triflate.The mechanism involves transmetallation, in which the substituent on the borane replaces a ligand on palladium, followed by reductive elimination to form the new C—C bond. 

In 1979, Kumada/Hayashi extended the scope of the palladium-catalyzed reaction using the diphosphine dppf to react alkyl Grignard reagents without any isomerization (Scheme 19.19) [24a, b]. Aryl bromides react at rt, which means that the dppf ligand accelerates the oxidative addition (electron-rich ligand) when compared to PPh. Remarkably, dppf also accelerates the reductive elimination cis and bulky ligand) and suppresses the p-hydride elimination. 

Complexes of internal alkynes of general formula Pd(7] -alkyne)(PR3)2 or Pd( 7 -alkyne)(diphos) have been reported, often prepared in the course of palladium-catalyzed reactions and other processes. Thus, most of them have been synthesized by decomposition of Pd(ii) complexes in the presence of the alkyne as shown in Equations (20) and (21). Insertion into a Pd-E bond and reductive elimination generates the silylated or stannylated alkene and Pd(0), which is trapped by the alkyne in excess. 

---