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Spatial pinning of globally inert pores in a superhydrophobic hydrogen-bonded organic framework for inverse ethane/ethylene separation

Youlie Cai, Jing-Hong Li, Xiaoyan Xiao, Runzhi Wei, Rui-Biao Lin, Banglin Chen, Junkuo Gao

2025Chemical Science14 citationsDOIOpen Access PDF

Abstract

. This work introduces a pivotal advancement in the precursor design strategy to precisely modulate secondary interaction mechanisms within porous organic frameworks, offering new horizons for customized pore engineering.

Topics & Concepts

Inertvan der Waals forceSorptionChemical physicsAdsorptionMaterials sciencePorosityChemical engineeringHydrogen bondNanotechnologyInert gasWork (physics)PolarHydrogenPorous mediumInverseHydrophobic effectWater vaporMetal-organic frameworkChemistryMicromodelSelectivityMoleculeChemical polarityContact angleMolecular dynamicsHydrophobePolarity (international relations)Core (optical fiber)Covalent Organic Framework ApplicationsMetal-Organic Frameworks: Synthesis and ApplicationsCarbon Dioxide Capture Technologies
Spatial pinning of globally inert pores in a superhydrophobic hydrogen-bonded organic framework for inverse ethane/ethylene separation | Litcius