Highly Selective O -Phenylene Bisurea Catalysts for ROP: Stabilization of Oxyanion Transition State by a Semiflexible Hydrogen Bond Pocket.
Jia ZhangKai Hin LuiRachele ZuninoYuan JiaRomain MorodoNiklas WarlinJames L HedrickGiovanni TalaricoRobert M WaymouthPublished in: Journal of the American Chemical Society (2024)
Organocatalyzed ring-opening polymerization (ROP) is a versatile technique for synthesizing biodegradable polymers, including polyesters and polycarbonates. We introduce o -phenylene bisurea (OPBU) (di)anions as a novel class of organocatalysts that are fast, easily tunable, mildly basic, and exceptionally selective. These catalysts surpass previous generations, such as thiourea, urea, and TBD, in selectivity ( k p / k tr ) by 8 to 120 times. OPBU catalysts facilitate the ROP of various monomers, achieving high conversions (>95%) in seconds to minutes, producing polymers with precise molecular weights and very low dispersities ( Đ ≈ 1.01). This performance nearly matches the ideal distribution expected from living polymerization (Poisson distribution). Density functional theory (DFT) calculations reveal that the catalysts stabilize the oxyanion transition state via a hydrogen bond pocket similar to the "oxyanion hole" in enzymatic catalysis. Both experimental and theoretical analyses highlight the critical role of the semirigid o -phenylene linker in creating a hydrogen bond pocket that is tight yet flexible enough to accommodate the oxyanion transition state effectively. These new insights have provided a new class of organic catalysts whose accessibility, moderate basicity, excellent solubility, and unparalleled selectivity and tunability open up new opportunities for controlled polymer synthesis.
Keyphrases
- transition metal
- density functional theory
- highly efficient
- molecular dynamics
- metal organic framework
- visible light
- blood brain barrier
- drug delivery
- minimally invasive
- genome wide
- molecular dynamics simulations
- gene expression
- ionic liquid
- nitric oxide
- single cell
- molecular docking
- dna methylation
- escherichia coli
- single molecule
- candida albicans
- quantum dots
- biofilm formation
- cystic fibrosis