吸附
化学
范德瓦尔斯力
烷基
选择性
跟踪(心理语言学)
产量(工程)
存水弯(水管)
动能
化学工程
氧气
微量气体
微量
热力学
生产(经济)
纳米技术
选择性吸附
可扩展性
催化作用
作者
Miao Chang,Zitong Wang,Ruihan Wang,Minghui Liu,Yujie Wang,Dahuan Liu
出处
期刊:Angewandte Chemie
[Wiley]
日期:2025-10-23
卷期号:64 (51): e202515496-e202515496
被引量:7
标识
DOI:10.1002/anie.202515496
摘要
Abstract Highly efficient capture of trace C 3 H 6 from C 2 H 4 by physisorbents remains an enormous challenge to combine top‐rank separation performance with excellent stability and economical scalability. We, herein, built a single‐molecule C 3 H 6 trap that bears an opposite series of oxygen and dense alkyl groups distributed in an ultramicroporous [Al(OH)(trans‐CDC)] (Al‐CDC, trans‐H 2 CDC = trans‐1,4‐cyclohexanedicarboxylic acid). The ultra‐stable trap with well‐matched pore size and pore chemistry enables a record uptake (40.8 cm 3 (STP) g −1 ) at ultralow concentration, Henry coefficient (12685.5 cm 3 (STP) g −1 bar −1 ), initial adsorption heat difference (27.2 kJ mol −1 ), adsorption kinetic (0.49 min −1 ) and kinetic selectivity (3.1) for C 3 H 6 with one of the highest initial C 3 H 6 adsorption heats (50.5 kJ mol −1 ) and selectivity (16.3), establishing a novel benchmark for capture of trace C 3 H 6 . The C 3 H 6 adsorption mechanism is deciphered to be thermodynamically driven owing to the synergism of multiple hydrogen‐bonding and van der Waals (vdW) forces. Breakthrough tests validate that Al‐CDC owns a record C 2 H 4 productivity (≥99.999%) of 410.5 cm 3 (STP) g −1 for trace C 3 H 6 capture with excellent reproducibility. The cost‐effective scalable production with the cheapest cost (508.9 $ kg −1 ) and highest space‐time yield (4564.8 kg m −3 day −1 ) and shaping of Al‐CDC is realized with unaffected structural property and capture performance.
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