Tuning Pd Catalyst Performance in Transfer Hydrogenation Reactions: Ligand Electronic Properties, Hydrogen Source and Ionic Liquid-Mediated-Effects.

We report a systematic study of phenanthroline-Pd(II) complexes featuring electronically tuned amide substituents (alkyl: ; carboxylic: /) for the transfer hydrogenation (TH) of -cinnamic acid (-CA) to hydrocinnamic acid (HCA) in imidazolium-based ionic liquids (ILs). The electronic effects of ligand substituents, hydrogen source (FA/TEA mixtures vs ammonium formate), and solvent environment on catalytic activity were evaluated. Alkylamide-substituted [Pd()Cl] displayed superior performance with FA/TEA via solution-phase hydride transfer, whereas electron-deficient [Pd()Cl] were more effective with ammonium formate under a mixed homogeneous/heterogeneous regime. Ionic liquids significantly enhanced catalyst performance compared to the conventional organic solvent DMF, with minor changes in IL cations or anion causing substantial variations in conversion. Mechanistic studies, including MS, UV-Vis, NMR, electrochemistry (using Pt(II) analogues), and gas-evolution analyses, revealed that monoformate Pd intermediates and their evolution depend on the electronic properties of the ligands and the hydrogen donor, directing productive or unproductive pathways. This work highlights the delicate interplay between ligand design, hydrogen source, and ionic liquid microenvironment in controlling Pd-catalyzed transfer hydrogenation and provides a platform for designing efficient, tunable Pd-based TH systems.