摘要
Ionic liquids(ILs)provide a promising way for efficient absorption and separation of ammonia(NH_(3))due to their extremely low vapor pressures and adjustable structures.However,the understanding of absorption mechanisms especially in terms of theoretical insights is still not very clear,which is crucial for designing targeted ILs.In this work,a universal method that integrates density functional theory and molecular dynamic simulations was proposed to study the mechanisms of NH_(3) absorption by protic ionic liquids(PILs).The results showed that the NH_(3) absorption performance of the imidazolium-based PILs([BIm][X],X=Tf_(2)N,SCN and NO_(3))is determined by not only the hydrogen bonding between the N atom in NH_(3) and the protic site(H–N_(3))on the cation but also the cation–anion interaction.With the increase in NH_(3) absorption capacity,the hydrogen bonding between[BIm][Tf_(2)N]and NH_(3) changed from orbital dominated to electrostatic dominated,so 3.0 mol NH_(3) per mol IL at 313.15 K and 0.10 MPa was further proved as a threshold for NH_(3) capacity of[BIm][Tf_(2)N]by the Gibbs free energy results,which agrees well with the experimental results.Furthermore,the anions of[BIm][X]could also compete with NH_(3) for interaction with H-N_(3) of the cation,which weakens the interaction between the cation and NH_(3) and then decreases the NH_(3) absorption ability of PILs.This study provides further understanding on NH_(3) absorption mechanisms with ILs,which will guide the design of novel functionalized ILs for NH_(3) separation and recovery.
基金
financially supported by the National Key R&D Program of China(2020YFA0710200)
the National Natural Science Foundation of China(22122814,21890764 and 21838010)
the Youth Innovation Promotion Association of the Chinese Academy of Sciences(2018064)
the Major Scientific and Technological Innovation Project of Shandong Province of China(2019JZZY010518).
