Journal
JOURNAL OF MEMBRANE SCIENCE
Volume 677, Issue -, Pages -Publisher
ELSEVIER
DOI: 10.1016/j.memsci.2023.121631
Keywords
Layered hydroxide salts; 2D membrane; In situ fabrication; Molecular sieving; H-2/CO2 separation
Categories
Ask authors/readers for more resources
Researchers have successfully fabricated a low-cost two-dimensional membrane by using a rapid in situ growth strategy at room temperature, which has a few-layered thickness and intriguing surface undulations. This membrane showed excellent molecular sieving ability and opens up a new avenue for future scale-up of membranes.
Two-dimensional (2D) materials have demonstrated their superiorities as molecular sieve membranes for strategic gas separations. The promotion of these 2D membranes is confronted with great challenges such as elaborate fabrication procedures and expensive raw materials. Layered hydroxide salts (LHSs) are a kind of lamellar material involving economical ingredients and are quite easy-to-fabricate. However, they have yet to be developed into gas separation membranes and their separation potential has not been investigated, despite their merits. Here, we report the successful fabrication of ultrathin Zn-5(OH)(8)(NO3) 2 center dot 2H(2)O membranes by using a rapid and facile in situ growth strategy at room temperature. By virtue of the few-layered membrane thickness, the obtained membranes exhibited intriguing surface undulations, which endowed the membranes with extremely tortuous interlayer channels and therefore an auspicious molecular sieving ability. Consequently, these membranes showed an optimal H-2/CO2 mixture separation selectivity of 792 +/- 38 and a remarkable H-2 permeance of 1607 +/- 99 GPU. Moreover, with a demonstration of a gentle framework dehydration, the molecular sieving capacity of the LHS membrane was further sharpened at 150 degrees C owing to the narrowed interlayer channels. This work introduced a low-cost 2D membrane and manifested the advantages of fabricating few-layered 2D membranes, opening a new avenue for membrane future scale-up.
Authors
I am an author on this paper
Click your name to claim this paper and add it to your profile.
Reviews
Recommended
No Data Available