Catalytic cycle and off-cycle steps in the palladium-catalyzed fluorination of aryl bromide with biaryl monophosphine ligands: Theoretical free energy profile

Palladium catalyzed fluorination of aryl halides with inorganic fluoride salts has been a challenge transformation during several decades. The successful catalysis came with the use of biaryl monophosphine ligand. However, the catalytic process suffers of the problem of off-cycle transformation as ligand modification and formation of regioisomers, which means that more ligand design is necessary. In this work, the complete free energy profile for the catalysis using tBuBrettPhos ligand was determined by reliable theoretical calculations, including the transmetalation step. The calculations have indicated that monocoordination by phosphine and the bulky groups in the tBuBrettPhos ligand, which has strong repulsion to the coordinating bromide ion, are critical to achieve low activation barriers for reductive elimination. The ligand modification transition state was found and involves migration of the coordinating aryl group. The mechanism of regioisomers formation, an important drawback of this methodology, was also found and corresponds to the elimination of HF without participation of CsF, forming a benzyne intermediate coordinating to the palladium. The return of the HF can take place by proton donation to any carbon of the benzyne, which produces the isomerization. These findings indicate that more rational ligand design can be done to produce more effective catalysis. The theoretically determined rate law and the overall ?G? are in excellent agreement with experimental data.

Automated summary

The successful palladium catalysis using biaryl monophosphine ligand for fluorination of aryl halides with inorganic fluoride salts has been a challenge transformation for several decades. However, the catalytic process suffers from the issue of off-cycle transformation due to ligand modification and formation of regioisomers, highlighting the importance of further ligand design. The theoretical calculations have provided insights into the mechanism of the catalysis and regioisomers formation, indicating the potential for more effective catalysis through rational ligand design.