The Suzuki–Miyaura reaction is the most practiced palladium-catalyzed, cross-coupling reaction because of its broad applicability, low toxicity of the metal (B), and the wide variety of commercially available boron substrates. A wide variety of boronic acids and esters, each with different properties, have been developed for this process. Despite the popularity of the Suzuki–Miyaura reaction, the precise manner in which the organic fragment is transferred from boron to palladium has remained elusive for these reagents. Herein, we report the observation and characterization of pretransmetalation intermediates generated from a variety of commonly employed boronic esters. The ability to confirm the intermediacy of pretransmetalation intermediates provided the opportunity to clarify mechanistic aspects of the transfer of the organic moiety from boron to palladium in the key transmetalation step. A series of structural, kinetic, and computational investigations revealed that boronic esters can transmetalate directly without prior hydrolysis. Furthermore, depending on the boronic ester employed, significant rate enhancements for the transfer of the B-aryl groups were observed. Overall, two critical features were identified that enable the transfer of the organic fragment from boron to palladium: (1) the ability to create an empty coordination site on the palladium atom and (2) the nucleophilic character of the ipso carbon bound to boron. Both of these features ultimately relate to the electron density of the oxygen atoms in the boronic ester.
Herein, a mild and operationally simple method for the Suzuki−Miyaura cross-coupling of boronic esters is described. Central to this advance is the use of the organic-soluble base, potassium trimethylsilanolate, which allows for a homogeneous, anhydrous crosscoupling. The coupling proceeds at a rapid rate, often furnishing products in quantitative yield in less than 5 min. By applying this method, a >10-fold decrease in reaction time was observed for three published reactions which required >48 h to reach satisfactory conversion.
Reaction conditions have been developed
for refractory heteroaryl–heteroaryl
Suzuki–Miyaura cross-couplings. The reported method employs
neopentyl heteroarylboronic esters as nucleophiles, heteroaryl bromides
and chlorides as the electrophiles, and the soluble base potassium
trimethylsilanolate (TMSOK) under anhydrous conditions. The addition
of trimethyl borate enhances reaction rates by several mechanisms,
including (1) solubilization of in situ-generated
boronate complexes, (2) preventing catalyst poisoning by the heteroatomic
units, and (3) buffering the inhibitory effect of excess TMSOK. The
use of this method enables cross-coupling of diverse reaction partners
including a broad range of π-rich and π-deficient heteroaryl
boronic esters and heteroaryl bromides. Reactions proceed in good
yields and short reaction times (3 h or less).
Carbene polymerization provides polyolefins that cannot be readily prepared from olefin monomers; however, controlled and living carbene polymerization has been a long-standing challenge. Here we report a new class of initiators, (π-allyl)palladium carboxylate dimers, which polymerize ethyl diazoacetate, a carbene precursor in a controlled and quasi-living manner, with nearly quantitative yields, degrees of polymerization >100, molecular weight dispersities 1.2-1.4, and well-defined, diversifiable chain ends. This method also provides block copolycarbenes that undergo microphase segregation. Experimental and theoretical mechanistic analysis supports a new dinuclear mechanism for this process.
Previous studies have shown that
the critical transmetalation step
in the Suzuki–Miyaura cross-coupling proceeds through a mechanism
wherein an arylpalladium hydroxide complex reacts with an aryl boronic
acid, termed the oxo-palladium pathway. Moreover, these same studies
have established that the reaction between an aryl boronate and an
arylpalladium halide complex (the boronate pathway) is prohibitively
slow. Herein, studies on isolated intermediates, along with kinetic
analysis, have demonstrated that the Suzuki–Miyaura reaction
promoted by potassium trimethylsilanolate (TMSOK) proceeds through
the boronate pathway, in contrast with other, established systems.
Furthermore, an unprecedented, binuclear palladium(I) complex containing
a μ-phenyl bridging ligand was characterized by NMR spectroscopy,
mass spectrometry, and computational methods. Density functional theory
(DFT) calculations suggest that the binuclear complex exhibits an
open-shell ground electronic state, and reaction kinetics implicate
the complex in the catalytic cycle. These results expand the breadth
of potential mechanisms by which the Suzuki–Miyaura reaction
can occur, and the novel binuclear palladium complex discovered has
broad implications for palladium-mediated cross-coupling reactions
of aryl halides.
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