Free radical olefin polymerization is well-known and commercially important. However, copolymerizations of ethylene with polar industrial monomers, such as vinyl acetate and acrylic acid, are increasingly complex, requiring high temperature and exceedingly high pressures. Further, such processes intrinsically lack precise control over the resulting polymer architecture, polymer molecular weight and incorporation of polar monomer. In view of these deficiencies, coordination polymerization has been explored for potential controllable strategies for the synthesis of polyolefins having various functionalities derived from the incorporation of a polar monomer. Two dominant classes of transition metal catalysts have been developed to date for copolymerization of ethylene and industrial polar monomers. The first class encompasses group 10 complexes coordinated by an α-diimine ligand, commonly referred to Brookhart-type catalysts. The remaining class employs neutral palladium complexes coordinated by a phosphine sulfonate (Drent-type). These two classes have persistent limitations. For Brookhart catalysts, complex stability is limited for polymerizations conducted above room temperature. Even state-of-the-art Brookhart catalysts are persistent for only about 15 minutes at or above 90° C. While Drent catalysts generally exhibit greater thermal stability, they typically produce low-molecular weight copolymers of ethylene and polar industrial monomers and/or turnover with poor rates. Therefore, new transition metal catalysts are required for the production of polar functionalized polyolefins.