The role of mixed alkali metal cations on the formation of nanosized CHA zeolite from colloidal precursor suspension

A clear understanding of the crystal formation pathways of zeolites remains one of the most challenging issues to date. Here we investigate the synthesis of nanosized chabazite (CHA) zeolites using organic template-free colloidal suspensions by varying the time of aging at room temperature and the time of hydrothermal treatment at 90 degrees C. The role of mixed alkali metal cations (Na+, K+, Cs+) on the formation of CHA in the colloidal suspensions was studied. Increasing the aging time of the precursor colloidal suspension from 4 to 17 days resulted in faster crystallization of CHA nanocrystals (3 h instead of 7 h at 90 degrees C) to afford significantly smaller particles (60 nm vs 600 nm). During the crystallization a considerable change in the content of inorganic cations in the recovered solid material was observed to coincide with the formation of the CHA nanocrystals. The Na+ cations were found to direct the formation of condensed and pre-shaped aluminosilicate particles in the colloidal precursor suspensions, while K+ cations facilitated the formation of secondary building units (SBUs) of the CHA type framework structure such as d6r and cha cages, and the Cs+ cations promoted the long-range crystalline order facilitating the crystallization of stable zeolite nanocrystals. (C) 2021 Elsevier Inc. All rights reserved.

Automated summary

The synthesis of nanosized chabazite zeolites was investigated using organic template-free colloidal suspensions by adjusting the aging time and hydrothermal treatment time. Different alkali metal cations (Na+, K+, Cs+) were found to play distinct roles in the formation of CHA nanocrystals in the colloidal suspensions, influencing the crystallization speed and particle size.