Dual ionic liquids containing Bi-bridged bromide dizinc anion immobilized on CoFe2O4@polystyrenes: Intramolecular multicenter synergism and regulation for CO2 cycloaddition

Jing Chen, Qin Wu*, Daxin Shi, Yaoyuan Zhang, Kangcheng Chen, Hui Li, Baohua Xu, Hansheng Li

*Corresponding author for this work

Research output: Contribution to journalArticlepeer-review

Abstract

The synthesis of cyclic carbonates via CO2 cycloaddition holds significant promise in reducing CO2 concentrations. The dizinc bromide ionic liquid, with an intramolecular Bi-bridged bromide dizinc anion structure, was constructed. This dual ionic liquid was immobilized on the surface of CoFe2O4@polystyrenes to prepare the MPNPs-[ImCnZ][ZnBr3]2 catalysts with high activity, moderate reaction conditions, good stability, and easy separation and recovery. Without solvents or co-catalysts, a 99.5% propylene oxide conversion and a 100.0% cyclic carbonates selectivity was obtained. Experimental studies and DFT calculations pointed that the appropriate alkyl chain length between the bis-imidazolium cations facilitated the formation of [ZnBr3]2. The synergistic effect between this dimer and the bis-imidazolium cations made MPNPs-[ImC2Im][ZnBr3]2 an efficient catalyst for CO2 cycloaddition owning to the intramolecular electronic effect and spatial effect. The catalyst integrates the advantages of bimetal halide ionic liquid, intramolecular multicentral synergy, and efficient separation and recovery, opening up a novel avenue for industrial applications.

Original languageEnglish
Article number129734
JournalSeparation and Purification Technology
Volume355
DOIs
Publication statusPublished - 1 Mar 2025

Keywords

  • CO cycloaddition
  • Density functional theory
  • Dizinc bromide ionic liquids
  • Intramolecular multicenter synergism
  • Magnetic separations

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