Luciano Sanchez Merlinsky, Daniel Hemmeter, Prof. Dr. Luis M. Baraldo, Dr. Florian Maier, Prof. Dr. Hans-Peter Steinrück, Prof. Dr. Federico J. Williams
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引用次数: 0
摘要
控制离子液体(IL)表面金属复合物的局部浓度是一个备受追捧的目标,因为它在支撑离子液相催化(SILP)中具有举足轻重的影响。同样重要的是,由于环境问题,要避免使用全氟和多氟物质。在此,我们以亲水性 IL [C2C1Im][OAc]为溶剂,研究了具有不同长度和形状的无氟烷基侧基的 Ru 多吡啶络合物的表面富集。在多吡啶配体中加入了额外的带电羧酸基团,以增加配合物在 IL 中的溶解度。根据角度分辨 X 射线光电子能谱的推断,当配体系统被长的疏水烷基侧链官能化时,配合物主要定位于 IL/真空界面。相反,如果存在较短或较笨重的取代基,则观察不到表面富集。我们对 0.05 %mol 至 1 %mol 溶液中无氟侧基的浮标状行为进行了研究。有趣的是,表面饱和大约发生在 0.5 %mol 时,这有利于高表面积催化系统(如 SILP 催化剂)的高效运行。
Unlocking the Fluorine-Free Buoy Effect: Surface-Enriched Ruthenium Polypyridine Complexes in Ionic Liquids
Controlling the local concentration of metal complexes at the surface of ionic liquids (ILs) is a highly sought-after objective due to its pivotal implications in supported ionic liquid phase (SILP) catalysis. Equally important is to avoid per- and polyfluorinated substances due to environmental concerns. Herein, we investigate the surface enrichment of Ru polypyridyl complexes with fluorine-free alkylic side groups of varying lengths and shapes, using the hydrophilic IL [C2C1Im][OAc] as solvent. Additional charged carboxylate groups are included into the polypyridyl ligands to increase the solubility of the complex in the IL. When the ligand system is functionalized with long and hydrophobic alkyl side chains, the complex predominantly localizes at the IL/vacuum interface, as deduced from angle-resolved X-ray photoelectron spectroscopy. Conversely, in the presence of short or more bulky substituents, no surface enrichment is observed. This buoy-like behaviour with fluorine-free side groups is explored for 0.05 %mol to 1 %mol solutions. Intriguingly, surface saturation occurs at approximately 0.5 %mol, which is beneficial to the efficient operation of catalytic systems featuring high surface areas, such as SILP catalysts.
期刊介绍:
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