Journal
INORGANIC CHEMISTRY
Volume 60, Issue 13, Pages 9912-9931Publisher
AMER CHEMICAL SOC
DOI: 10.1021/acs.inorgchem.1c01159
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Funding
- NSF [CHE-1465188, 1954612, DGE 1752814, 1106400]
- NIH [S10OD024998]
- Direct For Mathematical & Physical Scien [1954612] Funding Source: National Science Foundation
- Division Of Chemistry [1954612] Funding Source: National Science Foundation
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This study demonstrates the formation of a diverse array of organic and organometallic products containing newly formed C-C bonds via successive methyl transfers from di-, tri-, and tetramethyl Ta(V) precursors to unsaturated small molecule substrates. The reactions of Ta(V) methyl complexes with CO led to the formation of oxo enolate Ta(V) products and imido enamine Ta(V) products. Surprisingly, a new dianionic scorpionate ligand was formed through a reaction involving methyl transfer from the metal center. Mechanistic studies revealed a new reaction pathway in early transition metal chemistry.
We demonstrate the formation of a diverse array of organic and organometallic products containing newly formed C-C bonds via successive methyl transfers from di-, tri-, and tetramethyl Ta(V) precursors to unsaturated small molecule substrates under mild conditions. The reactions of Ta(V) methyl complexes 1-X [H2B((Mes)Im)(2)]TaMe3X (X = Me, Cl; Im = imidazole, Mes = 2,4,6-trimethylphenyl) with CO led to oxo enolate Ta(V) products, in which the enolate ligands were constructed from Ta-Me groups and two equivalents of CO. Similarly, the reaction of 1-Me with CNXyl yielded an imido enamine Ta(V) product. Surprisingly, 1-Cl reacted with CNXyl (1 equiv) at the borate backbone of the [H2B((Mes)Im)(2)] ligand with concomitant methyl transfer from the metal center to form a new, dianionic scorpionate ligand that supported a Ta(V) dimethyl chloro complex (6). Treatment of 1-Cl with further CNXyl led to an azaallyl scorpionate complex, and an imido isocyanide scorpionate complex, along with propene and xylyl ketenimine. Complex 6 reacted with CO to yield a pinacol scorpionate complex 10.a new reaction pathway in early transition metal chemistry. Mechanistic studies revealed that this proceeded via migratory insertion of CO into a Ta-Me group, followed by methyl transfer to form an eta(2)-acetone intermediate. Elimination of acetone furnished a CO-stabilized Ta(III) intermediate capable of rebinding and subsequently coupling two equivalents of CO-derived acetone to form the pinacol ligand in 10.
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