The mechanism of the [PdL4]-catalyzed couplings between R−OTf (R = pentahalophenyl; L =
PPh3, AsPh3) and Sn(CHCH2)Bu3 has been studied. The addition of LiCl favors the coupling for L = AsPh3
in THF but retards it for L = PPh3. Separate experiments show that for L = AsPh3, LiCl accelerates the
otherwise very slow and rate-determining oxidative addition of the aryl triflate to [PdL4], leading to trans-[PdRClL2]. Therefore, the overall process is accelerated. For L = PPh3, the rate-determining step is the
transmetalation. Complex trans-[PdRXL2], with X = Cl, is formed in the presence of LiCl, whereas an
equilibrium mixture mainly involving species with X = TfO, L, or S (S = solvent) is established in the absence
of LiCl. Since the transmetalation is slower for X = Cl than for the other complexes, the overall process is
retarded by addition of LiCl. The transmetalation in complexes trans-[PdRXL2], with X = Cl, follows the
SE2(cyclic) mechanism proposed in Part 1 (Casado, A. L.; Espinet, P. J. Am. Chem. Soc.
1998, 120, 8978−8985), giving the coupling product RCHCH2 directly. For X = TfO or L, rather stable intermediates trans-[PdR(CHCH2)L2] are detected, supporting an SE2(open) mechanism. The key intermediates undergoing
transmetalation in the conditions and solvents most commonly used in the literature have been identified. The
operation of SE2(cyclic) and SE2(open) pathways emphasizes common aspects of the Stille reaction with the
Hiyama reaction where, using R2SiF3 that is chiral at the α-carbon of R2, retention or inversion at the
transmetalated chiral carbon can be induced. This helps us to understand the contradictory stereochemical
outcomes in the literature for Stille couplings using R2SnR3 derivatives that are chiral at the α-carbon of R2
and suggests that stereocontrol of the Stille reaction might be achieved.
The kinetics of the Stille reaction between C 6 Cl 2 F 3 I and PhCCSnBu 3 have been studied for the whole catalytic system and for transmetalations as separate steps. The use of (trifluorodichlorophenyl)palladium derivatives slows down the reactions and allows for the observation of the intermediates cis-and trans-[Pd(C 6 Cl 2 F 3 )I(PPh 3 ) 2 ]. The first is formed in the oxidative addition step and isomerizes to the second. Both were studied as catalysts for the whole cycle. The kinetic study compares the relevance of the transmetalation step on each isomer. The competing transmetalations produce both cis-and trans-[Pd(C 6 Cl 2 F 3 )(PhCC)(PPh 3 ) 2 ]. The former undergoes very fast C-C coupling, while the second accumulates in solution due to extremely slow isomerization. Thus, the system is a case study of the effect of competing pathways in the Stille reaction and its consequences on the performance of the catalytic process.
Neutral palladium(II) complexes [Pd(Rf)X(P-L)] (Rf = 3,5-C6Cl2F3, X = Cl, I, OTf) with P-P (dppe and dppf) and P-N (PPh2(bzN)) ligands have chelated structures in the solid-state, except for P-L...
A reinvestigation of the NMR spectra of the complexes (NBu4)2[M2(mu-LL)2R4] (M = Pd, Ni, Pt, LL = pyrazolate (pz), 3,5-dimethylpyrazolate (dmpz), 3-methylpyrazolate (mpz), indazolate (indz), R = C6F5; M = Pd, LL = pz, dmpz, mpz, indz, R = 2,4,6-C6F3H2) shows that the boat-shaped dimeric structures of their anions are quite stable in solution, and the previously proposed fast equilibria or dissociations to give species such as [R2M(N-N)(acetone)]-, [R2M(acetone)2] + 2dmpz-, or [R2M(N1-N2)(acetone)]- + [R2M(N2-N1)(acetone)]- in no case occur. A mixture of the two diastereoisomers (head-to-head, HH, and head-to-tail, HT) is present for the asymmetrically substituted azolates (mpz and indz), in a ratio ranging from 1:7 to 1:30 for the different complexes. Strong through-space coupling between the endo ortho fluorine nuclei of different MR2 fragments is observed in the 19F NMR spectra of these diastereoisomers whose boatlike structures place these atoms at short distances.
The synthesis of aryl−alkynyl compounds is usually achieved via Sonogashira catalysis, but this is inefficient for fluorinated aryls. An alternative method reported by Shirakawa and Hiyama, using alkynylstannanes and hemilabile PN ligands, works apparently fine for conventional aryls, but it is also poor for fluorinated aryls. The revision of the unusual literature cycle reveals the existence and nature of unreported byproducts and uncovers coexisting cycles and other aspects that explain the reasons for the conflict. This knowledge provides a full understanding of the real complexity of these aryl/alkynylstannane systems and the deviations of their evolution from that of a classic Stille process, providing the clues to design several very efficient alternatives for the catalytic synthesis of the desired Ar F −alkynyl compounds in almost quantitative yield. The same protocols are also very efficient for the catalytic synthesis of alkynyl−alkynyl' hetero-and homocoupling.
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