One-pot synthesis of FeCu-SSZ-13 zeolite with superior performance in selective catalytic reduction of NO by NH3 from natural aluminosilicates

[Display omitted] •Highly crystalline FeCu-SSZ-13 was one-pot synthesized from natural minerals.•Neither silicon, aluminum, and iron-containing chemicals were used.•The synthesized zeolite has small crystallize size and large specific surface area.•More iron and copper species are incorporated into...

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Published in:Chemical engineering journal (Lausanne, Switzerland : 1996) Switzerland : 1996), 2020-10, Vol.398, p.125515, Article 125515
Main Authors: Yue, Yuanyuan, Liu, Ben, Qin, Peng, Lv, Nangui, Wang, Tinghai, Bi, Xiaotao, Zhu, Haibo, Yuan, Pei, Bai, Zhengshuai, Cui, Qingyan, Bao, Xiaojun
Format: Article
Language:English
Subjects:
FeCu-SSZ-13 zeolite
Natural minerals
One-pot synthesis
Selective catalytic reduction
Superior performance
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Summary:[Display omitted] •Highly crystalline FeCu-SSZ-13 was one-pot synthesized from natural minerals.•Neither silicon, aluminum, and iron-containing chemicals were used.•The synthesized zeolite has small crystallize size and large specific surface area.•More iron and copper species are incorporated into the framework of FeCu-SSZ-13.•The resultant FeCu-SSZ-13 shows outstanding catalytic performance in NH3-SCR. Heterobimetallic zeolites have been considered as highly efficient catalysts to reduce nitrogen oxide emissions, but economic and sustainable preparation methods have been lacking. This paper presents an economic and sustainable one-pot synthesis strategy to prepare the heterobimetallic FeCu-SSZ-13 zeolite (FeCu-SSZ-13M) with high crystallinity via the mesoscale depolymerization-reorganization of natural aluminosilicate minerals without the use of any synthetic silicon-, aluminum-, and iron-containing chemicals. Systematic characterization results reveal that the resultant FeCu-SSZ-13M sample has smaller crystallize size, larger specific surface area and pore volume (especially external specific surface area and mesopore volume), lower acid strength and more isolated Cu2+ and framework Fe3+ ions when compared with Cu-SSZ-13C and FeCu-SSZ-13C prepared from conventional precursors. Therefore, it exhibits outstanding catalytic performance (such as super-wide reaction temperature window, excellent hydrothermal stability, high H2O and SO2 tolerance, and good gaseous hourly space velocity flexibility) in the selective catalytic reduction of NO by NH3. Our research contributes to the design and synthesis of an efficient environmental protection catalyst in an economic and sustainable manner.
ISSN:1385-8947
1873-3212
DOI:10.1016/j.cej.2020.125515