A novel strategy for synthesizing the high-performance
thin and
compact sodalite zeolite membrane over rough α-Al2O3 support was developed. The synthesis involved the deposition
of a layer of flaky MCM-22 zeolite crystals over support and the subsequent
hydrothermal crystallization of sodalite zeolite. It was identified
that the sodalite zeolite membrane possessed a thickness of ca. 700
nm with almost no defect, and a water/ethanol separation factor higher
than 10 000 at a permeation flux of 4.4 kg·m–2·h–1 could be achieved. A possible mechanism
for the formation of high-performance sodalite zeolite membrane was
also proposed, which involved first the decomposition of MCM-22 zeolite
crystals into small fragments containing double six-membered rings
(D6R) and subsequently the nucleation and crystallization of sodalite
initiated by the D6R-containing species over the surface of support
from the strongly alkali synthesis sol. The study showed that the
predeposition of a layer of flaky MCM-22 zeolite crystals over the
surface of support was crucial for the generation of thin and compact
sodalite membranes, as it not only improved the surface flatness but
also led to the in situ nucleation and crystallization of sodalite
zeolite crystals. This method combines 2D-material film-forming technology
with 3D-material film-forming technology, thus providing a new approach
for preparing thin and defect-free membranes.
Reticulated hydrotalcite interlayer controls infiltration of active ingredients into the support, improving the quality and stability of the zeolite membrane.
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