How solvents affect the stability of cationic Rh() diphosphine complexes: a case study of MeCN coordination

Cationic rhodium( i ) diphosphine complexes, referred to as Schrock-Osborn catalysts, are privileged homogeneous catalysts with a wide range of catalytic applications. The coordination of solvent molecules can have a significant influence on reaction mechanisms and kinetic scenarios. Although solvent binding is well documented for these rhodium species, comparative quantifications for structurally related systems are not available to date. We present a method for systematic investigation and quantification of this important parameter, using MeCN which replaces diolefins and forms stable Rh( i ) MeCN complexes. Using UV-vis and 31 P{ 1 H} NMR spectroscopy we determine and compare stability constants of different [Rh(PP)(NBD)]BF 4 and [Rh(PP)(COD)]BF 4 complexes (PP = diphosphine; COD = 1,5-cyclooctadiene; NBD = 2,5-norbornadiene) and discuss the influence of PP ligands and reaction temperature. A DFT study reveals the dependence of the stability on the thermodynamics of the exchange reaction. Using variable temperature NMR spectroscopy, the first mixed solvate complex could be verified as an intermediate in the MeCN-MeOH exchange. We present a method for the systematic investigation and quantification of the stability of solvate complexes of the type [Rh(diphosphine)(solvent) 2 ] + , using MeCN which replaces diolefins and forms stable Rh( i ) MeCN complexes.