A catalytic protocol to convert aryl and heteroaryl chlorides to the corresponding trifluoromethyl sulfides is reported herein. It relies on a relatively inexpensive Ni(cod)2/dppf (cod = 1,5-cyclooctadiene; dppf = 1,1'-bis(diphenylphosphino)ferrocene) catalyst system and the readily accessible coupling reagent (Me4N)SCF3. Our computational and experimental mechanistic data are consistent with a Ni(0)/Ni(II) cycle and inconsistent with Ni(I) as the reactive species. The relevant intermediates were prepared, characterized by X-ray crystallography, and tested for their catalytic competence. This revealed that a monomeric tricoordinate Ni(I) complex is favored for dppf and Cl whose role was unambiguously assigned as being an off-cycle catalyst deactivation product. Only bidentate ligands with wide bite angles (e.g., dppf) are effective. These bulky ligands render the catalyst resting state as [(P-P)Ni(cod)]. The latter is more reactive than Ni(P-P)2, which was found to be the resting state for ligands with smaller bite angles and suffers from an initial high-energy dissociation of one ligand prior to oxidative addition, rendering the system unreactive. The key to effective catalysis is hence the presence of a labile auxiliary ligand in the catalyst resting state. For more challenging substrates, high conversions were achieved via the employment of MeCN as a traceless additive. Mechanistic data suggest that its beneficial role lies in decreasing the energetic span, therefore accelerating product formation. Finally, the methodology has been applied to synthetic targets of pharmaceutical relevance.
Primary aliphatic amines are important building blocks in organic synthesis due to the presence of a synthetically versatile NH group. N-functionalization of primary amines is well established, but selective C-functionalization of unprotected primary amines remains challenging. Here, we report the use of CO as an activator for the direct transformation of abundant primary aliphatic amines into valuable γ-lactams under photoredox and hydrogen atom transfer (HAT) catalysis. Experimental and computational studies suggest that CO not only inhibits undesired N-alkylation of primary amines, but also promotes selective intermolecular HAT by an electrostatically accelerated interaction between the in situ-generated negatively charged carbamate and the positively charged quinuclidinium radical. This electrostatic attraction overwhelms the inherent bond dissociation energies which suggest that HAT should occur unselectively. We anticipate that our findings will open up new avenues for amine functionalizations as well as selectivity control in HAT reactions.
The
direct introduction of the valuable SCF3 moiety into organic
molecules has received considerable attention. While it can be achieved
successfully for aryl chlorides under catalysis with Ni0(cod)2 and dppf, this report investigates the Ni-catalyzed
functionalization of the seemingly more reactive aryl halides ArI
and ArBr. Counterintuitively, the observed conversion triggered by
dppf/Ni0 is ArCl > ArBr > ArI, at odds with bond
strength preferences. By a combined computational and experimental
approach, the origin of this was identified to be due to the formation
of (dppf)NiI, which favors β-F elimination as a competing
pathway over the productive cross-coupling, ultimately generating
the inactive complex (dppf)Ni(SCF2) as a catalysis dead
end. The complexes (dppf)NiI–Br and (dppf)NiI–I were isolated and resolved by X-ray crystallography.
Their formation was found to be consistent with a ligand-exchange-induced
comproportionation mechanism. In stark contrast to these phosphine-derived
Ni complexes, the corresponding nitrogen-ligand-derived species were found to be likely competent catalysts
in oxidation state I. Our computational studies of N-ligand derived
NiI complexes fully support productive NiI/NiIII catalysis, as the competing β-F elimination is disfavored.
Moreover, N-derived NiI complexes are predicted to be more
reactive than their Ni0 counterparts in catalysis. These
data showcase fundamentally different roles of NiI in carbon–heteroatom
bond formation depending on the ligand sphere.
While chemoselectivities in Pd0‐catalyzed coupling reactions are frequently non‐intuitive and a result of a complex interplay of ligand/catalyst, substrate, and reaction conditions, we herein report a general method based on PdI that allows for an a priori predictable chemoselective Csp2
−Csp2
coupling at C−Br in preference to C−OTf and C−Cl bonds, regardless of the electronic or steric bias of the substrate. The C−C bond formations are extremely rapid (<5 min at RT) and are catalyzed by an air‐ and moisture‐stable PdI dimer under open‐flask conditions.
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