What question did this study set out to answer?

The research aims to improve the performance of Cu-triazolate MOFs in dehydrating azeotropic ethanol mixtures through mixed-linker strategies.

January 22, 2026

Crystal Engineering on Cu‐Triazolate MOFs via Mixed‐Linker Modulation for Selective Azeotropic Ethanol Dehydration

Key Points

The research aims to improve the performance of Cu-triazolate MOFs in dehydrating azeotropic ethanol mixtures through mixed-linker strategies.
Developed a mixed-linker synthetic approach to modify Cu-Tz MOFs.
Incorporated amino and thioether-functionalized triazoles.
Analyzed the effects of linker modification on framework properties after thermal activation.
The mixed-linker Cu-Tz MOFs demonstrated increased hydrophilicity and porosity.
Revealed accessible Cu(II) open metal sites post-activation.
Exceeded parent Cu-Tz MOFs in separation efficiency for water-ethanol mixtures.

Abstract

ABSTRACT A mixed‐linker synthetic strategy was employed to engineer the morphology of copper–triazolate metal–organic frameworks (Cu‐Tz MOFs) through controlled crystal growth. By incorporating amino‐ and thioether‐functionalized triazole alongside the parent triazole linkers, the framework's hydrophilicity, pore cavity, and surface chemistry were systematically modulated. Upon thermal activation, the resulting mixed‐linker MOFs revealed accessible Cu(II) open metal sites, together with enhanced hydrophilicity and porosity within the framework. These features synergistically contribute to superior water removal performance from azeotropic water–ethanol mixtures, outperforming the parent CuTz in separation efficiency.

Crystal Engineering on Cu‐Triazolate MOFs via Mixed‐Linker Modulation for Selective Azeotropic Ethanol Dehydration

Key Points

Abstract

Cite This Study