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A thermally/chemically robust and easily regenerable anilato-based ultramicroporous 3D MOF for CO <sub>2</sub> uptake and separation

Noemi Monni, Eduardo Andrés-García, Katia Caamaño, Víctor García‐López, J.M. Clemente-Juan, Mónica Giménez‐Marqués, Mariangela Oggianu, Enzo Cadoni, Guillermo Mı́nguez Espallargas, Miguel Clemente‐León, Maria Laura Mercuri, Eugenio Coronado

2021Journal of Materials Chemistry A29 citationsDOIOpen Access PDF

Abstract

A novel anilato-based 3D ultramicroporous MOF is reported, displaying a significant balance of high CO 2 separation from CO 2 :N 2 and CO 2 :CH 4 gas mixtures, high thermal stability and high regenerability, a challenge in the separation technology industry.

Topics & Concepts

Thermal stabilityChemical engineeringGas separationSeparation (statistics)Materials scienceAir separationThermalChemistryOrganic chemistryComputer scienceMembraneThermodynamicsPhysicsBiochemistryEngineeringMachine learningOxygenMetal-Organic Frameworks: Synthesis and ApplicationsGas Sensing Nanomaterials and SensorsCovalent Organic Framework Applications
A thermally/chemically robust and easily regenerable anilato-based ultramicroporous 3D MOF for CO <sub>2</sub> uptake and separation | Litcius