Towards a selective synthetic route for cobalt amino acid complexes and their application in ring opening polymerization of rac-lactide

Abstract: Catalysts based on Co, amino acids, and 2,2-bipyridine present an attractive and economic alternative in ring opening polymerization, and possess advantageous ligand coordination properties combined with a variety of accessible oxidation states and coordination geometries.

“…33 By optimizing the reaction conditions, solvent, and order of reagent addition, Co( iii ) complexes were isolated as chloride salts in higher yields and free of cis -[Co(bipy) 2 Cl 2 ] and [Co(bipy) 2 (aa)]Cl formation. 32 Diastereotopic isomers were present as expected, and their ratio was analyzed by 1 H NMR spectroscopy, but no effort was made to perform their separation (see the ESI† and Experimental). Herein, the desired cationic species were prepared by employing a 1 : 2 ratio of bipy : aa followed by the subsequent addition of an equivalent of Co( ii ) chloride in aqueous ethanol.…”

“…32 Initially, trinuclear Co( ii ) complexes formed readily that reacted further with CoCl 2 to form cis -[Co(bipy) 2 Cl 2 ] complex as the kinetically favored product even in the presence of excess free amino acid. 32 An earlier report on alanine, glycine, and aminoisobutyrate Co( iii ) complexes obtained as perchlorate salts via a photolytic reaction reported the formation of at least two diastereotopic isomers and low yields along with a mixture of other bipy/aa complexes. 33 Preparations in DMSO and CH 3 CN from CoCl 2 yielded up to 40% yields and mixtures of products.…”

“…The structural elucidations of 6 and 9 reveal a hexacoordinated Co( iii ) center adopting a slightly distorted octahedral geometry analogous to the previously reported cobalt glycinate and leucinate complexes. 32 The molecular structure of 6 is shown in Fig. 2.…”

“…33 By optimizing the reaction conditions, solvent, and order of reagent addition, Co(III) complexes were isolated as chloride salts in higher yields and free of cis-[Co(bipy) 2 Cl 2 ] and [Co(bipy) 2 (aa)] Cl formation. 32 Diastereotopic isomers were present as expected, and their ratio was analyzed by 1 H NMR spectroscopy, but no effort was made to perform their separation (see the ESI † and Experimental). Herein, the desired cationic species were prepared by employing a 1 : 2 ratio of bipy : aa followed by the subsequent addition of an equivalent of Co(II) The HRMS data show that the molecular ions for complexes 1-9 are consistent with ionization resulting in the loss of a chloride counterion, with values corresponding to the molecular cation [Co(aa) 2 (bipy)] + , and that the isotope distribution patterns perfectly match those of the simulated patterns (Fig.…”

“…The results suggest the thermal activation of a precursor species. 32 To better understand the structure-reactivity relationship of cobalt-amino acids in CO 2 activation, this work targets the cobalt amino acid complexes to prepare highly efficient CO 2 / epoxide coupling catalysts.…”

Cobalt complexes with α-amino acid ligands catalyze the incorporation of CO₂into cyclic carbonates

“…33 By optimizing the reaction conditions, solvent, and order of reagent addition, Co( iii ) complexes were isolated as chloride salts in higher yields and free of cis -[Co(bipy) 2 Cl 2 ] and [Co(bipy) 2 (aa)]Cl formation. 32 Diastereotopic isomers were present as expected, and their ratio was analyzed by 1 H NMR spectroscopy, but no effort was made to perform their separation (see the ESI† and Experimental). Herein, the desired cationic species were prepared by employing a 1 : 2 ratio of bipy : aa followed by the subsequent addition of an equivalent of Co( ii ) chloride in aqueous ethanol.…”

“…32 Initially, trinuclear Co( ii ) complexes formed readily that reacted further with CoCl 2 to form cis -[Co(bipy) 2 Cl 2 ] complex as the kinetically favored product even in the presence of excess free amino acid. 32 An earlier report on alanine, glycine, and aminoisobutyrate Co( iii ) complexes obtained as perchlorate salts via a photolytic reaction reported the formation of at least two diastereotopic isomers and low yields along with a mixture of other bipy/aa complexes. 33 Preparations in DMSO and CH 3 CN from CoCl 2 yielded up to 40% yields and mixtures of products.…”

“…The structural elucidations of 6 and 9 reveal a hexacoordinated Co( iii ) center adopting a slightly distorted octahedral geometry analogous to the previously reported cobalt glycinate and leucinate complexes. 32 The molecular structure of 6 is shown in Fig. 2.…”

“…33 By optimizing the reaction conditions, solvent, and order of reagent addition, Co(III) complexes were isolated as chloride salts in higher yields and free of cis-[Co(bipy) 2 Cl 2 ] and [Co(bipy) 2 (aa)] Cl formation. 32 Diastereotopic isomers were present as expected, and their ratio was analyzed by 1 H NMR spectroscopy, but no effort was made to perform their separation (see the ESI † and Experimental). Herein, the desired cationic species were prepared by employing a 1 : 2 ratio of bipy : aa followed by the subsequent addition of an equivalent of Co(II) The HRMS data show that the molecular ions for complexes 1-9 are consistent with ionization resulting in the loss of a chloride counterion, with values corresponding to the molecular cation [Co(aa) 2 (bipy)] + , and that the isotope distribution patterns perfectly match those of the simulated patterns (Fig.…”

“…The results suggest the thermal activation of a precursor species. 32 To better understand the structure-reactivity relationship of cobalt-amino acids in CO 2 activation, this work targets the cobalt amino acid complexes to prepare highly efficient CO 2 / epoxide coupling catalysts.…”

Cobalt complexes with α-amino acid ligands catalyze the incorporation of CO₂into cyclic carbonates

Highly active cobalt(II) and copper(II) complexes supported by aminomethylquinoline mediating stereoselective ring‐opening polymerization of rac‐lactide

Metal Ion and Metal‐to‐Ligand Ratio Regulated Construction of Cu(II) and Co(II) Coordination Polymers as Efficient Catalysts for Ring‐Opening Polymerization of L‐Lactide