Covalent
organic frameworks (COFs) are promising hosts in heterogeneous
catalysis. Herein, we report a dual metalation strategy in a single
two-dimensional-COF TpBpy for performing a variety of C–N cross-coupling
reactions. [Ir(ppy)2(CH3CN)2]PF6 [ppy = 2-phenylpyridine], containing two labile CH3CN groups, and NiCl2 are used as iridium and nickel-metal
precursors, respectively, for postsynthetic decoration of the TpBpy
COF. Moving from the traditional approach, we focus on the COF-backbone
host for visible-light-mediated nickel-catalyzed C–N coupling
reactions. The controlled metalation and recyclability without deactivation
of both catalytic centers are unique with respect to previously reported
coupling strategies. We performed various photoluminescence, electrochemical,
kinetic, and Hammett correlation studies to understand the salient
features of the catalyst and reaction mechanism. Furthermore, theoretical
calculations delineated the feasibility of electron transfer from
the Ir center to the Ni center inside the confined pore of the TpBpy
COF. The dual metal anchoring within the COF backbone prevented nickel-black
formation. The developed protocol enables selective and reproducible
coupling of a diverse range of amines (aryl, heteroaryl, and alkyl),
carbamides, and sulfonamides with electron-rich, neutral, and poor
(hetero) aryl iodides up to 94% isolated yield. The reaction can also
be performed on a gram scale. Furthermore, to establish the practical
implementation of this approach, we have applied the synthetic strategy
for the late-stage diversification of the derivatives of ibuprofen,
naproxen, gemfibrozil, helional, and amino acids. The methodology
could also be applied to synthesize pharmacophore N,5-diphenyloxazol-2-amine
and Food and Drug Administration-approved drugs, including flufenamic
acid, flibanserin, and tripelennamine.
