Abstract
The separation of xylene isomers (para-, meta-, orth-) remains a great challenge in the petrochemical industry due to their similar molecular structure and physical properties. Porous materials with sensitive nanospace and selective binding sites for discriminating the subtle structural difference of isomers are urgently needed. Here, we demonstrate the adaptively molecular discrimination of xylene isomers by employing a NbOF52−-pillared metal–organic framework (NbOFFIVE-bpy-Ni, also referred to as ZU-61) with rotational anionic sites. Single crystal X-ray diffraction studies indicate that ZU-61 with guest-responsive nanospace/sites can adapt the shape of specific isomers through geometric deformation and/or the rotation of fluorine atoms in anionic sites, thereby enabling ZU-61 to effectively differentiate xylene isomers through multiple C–H···F interactions. ZU-61 exhibited both high meta-xylene uptake capacity (3.4 mmol g−1) and meta-xylene/para-xylene separation selectivity (2.9, obtained from breakthrough curves), as well as a favorable separation sequence as confirmed by breakthrough experiments: para-xylene elute first with high-purity (≥99.9%), then meta-xylene, and orth-xylene. Such a remarkable performance of ZU-61 can be attributed to the type anionic binding sites together with its guest-response properties.
Highlights
The separation of xylene isomers remains a great challenge in the petrochemical industry due to their similar molecular structure and physical properties
The electronic differences of the hydrogen atoms and the methyl groups in xylene isomers are more prominent than the aromatic ring, which inspired us to design a porous material with accessible electropositive/Lewis basic sites with promise to separate xylene isomers through the discrimination of the position difference of electropositive hydrogen atom in methyl groups of xylene isomers
The bulk purity of the anion-pillared metal–organic frameworks (MOFs) samples was confirmed by the powder X-ray diffraction (PXRD) tests (Supplementary Fig. 1)
Summary
The separation of xylene isomers (para-, meta-, orth-) remains a great challenge in the petrochemical industry due to their similar molecular structure and physical properties. Investigations indicate that the strong “cation-aromatic ring” interaction between the acidic sites of the zeolite and π-electrons of the xylene isomer along with xylene packing effects determine the separation selectivity and capacity. These cation sites exhibited low selectivity to xylene isomers[9,10,11,12]. Multi-component vapor-phase breakthrough experiments confirmed the efficient separation ability of ZU-61, with high-purity pX (≥99.9%) eluting first Both the uptake capacity of mX (3.4 mmol/g, 333 K, and 7.1 mbar) and mX/pX separation selectivity (2.9, obtained from breakthrough curves) are higher than most topperforming MOFs and the state-of-the-art NaY zeolite. A slight adjustment of crystal symmetry (space group) of ZU-61 was observed when accommodating oX
Sign-in/Register to view highlights & summary Sign-in/Register to access full text options 
Talk to us
Join us for a 30 min session where you can share your feedback and ask us any queries you have
Schedule a call
