AI Article Synopsis
- A comprehensive DFT study was conducted to clarify the mechanisms behind the Pd(0)-catalyzed transposition between aroyl chlorides and aryl iodides due to differing hypotheses from two experimental groups.
- The study revealed that the reaction involves the formation of a phosphonium salt and a key intermediate, followed by a process called ligand-enabled C-P bond metathesis.
- The transposition of functional groups is facilitated through an interpalladium ligand exchange mechanism, where two palladium centers operate as shuttle catalysts, highlighting the significance of both C-P bond metathesis and ligand exchange in the overall mechanism.
Article Abstract
A thorough DFT study was performed to unravel the true mechanism involved in the Pd(0)-catalyzed functional group transposition between aroyl chlorides and aryl iodides. Two different experimental groups proposed different mechanisms for the functional group transposition reaction. A careful assessment of experimental findings and thorough computational studies endorsed that the functional group transposition proceeds via phosphonium salt formation and ligand-enabled C-P bond metathesis, leading to the formation of the PhI and the intermediate . After the formation of the intermediate , the transposition of functional groups takes place through the interpalladium ligand exchange mechanism, where two palladium centers act as shuttle catalysts. In short, both C-P bond metathesis and interpalladium ligand exchange steps are crucial in the functional group transposition mechanism.
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| http://dx.doi.org/10.1021/acs.joc.2c00193 | DOI Listing |
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