![6-(Benzyloxy)-8-(2-bromoacetyl)-2H-benzo[b][1,4]oxazin-3(4H)-one structure](https://static.chemtradehub.com/structs/926/926319-53-1-2287.webp "6-(Benzyloxy)-8-(2-bromoacetyl)-2H-benzo[b][1,4]oxazin-3(4H)-one structure")
6-(Benzyloxy)-8-(2-bromoacetyl)-2H-benzo[b][1,4]oxazin-3(4H)-one
CAS Number:
926319-53-1
Molecular Formula:
C17H14BrNO4
Naphtha catalytic cracking to olefins over zirconia–titania catalyst
Literature Information
Publication Date
2021-09-27
DOI
10.1039/D1RE00290B
Impact Factor
4.239
Authors
Emad N. Shafei, Mohammed Z. Albahar, Mohammad F. Aljishi, Ali N. Aljishi, Ali S. Alnasir, Hameed H. Al-Badairy, Mohammed A. Sanhoob
View Original
Abstract
A zirconia–titania-based catalyst was synthesized by a co-participation method to study the catalytic cracking of heavy naphtha (dodecane) into high value-added olefins. The nanocrystal-sized catalysts were characterized and the cluster consisted of tetragonal ZrO2 incorporated into anatase TiO2. The catalyst was stable from hydrogen reduction while the surface acidity was increased as more ZrO2 was incorporated into the TiO2 framework. The catalytic cracking of naphtha was increased as the moderate catalytic acidity strength increased and the 50% Zr–Ti oxide catalyst delivered higher conversion between 85–95% with olefin yield around 55–60%. The surface acidity of the Zr–Ti catalyst promoted more cyclization reactions to produce benzene, toluene, and xylene (BTX). The study investigated steam catalytic cracking, which was slightly improved using a lower acidic Zr–Ti catalyst, while the propylene/ethylene ratio was unchanged. The time-on-stream study highlighted the stability of the catalyst with ZrO2 incorporated into the TiO2 framework, to promote olefin yield from naphtha catalytic cracking.
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Source Journal
Reaction Chemistry & Engineering
CiteScore:
0
Self-citation Rate:
8.8%
Articles per Year:
284
Reaction Chemistry & Engineering is an interdisciplinary journal reporting cutting-edge research focused on enhancing the understanding and efficiency of reactions. Reaction engineering leverages the interface where fundamental molecular chemistry meets chemical engineering and technology. Challenges in chemistry can be overcome by the application of new technologies, while engineers may find improved solutions for process development from the latest developments in reaction chemistry. Reaction Chemistry & Engineering is a unique forum for researchers whose interests span the broad areas of chemical engineering and chemical sciences to come together in solving problems of importance to wider society. All papers should be written to be approachable by readers across the engineering and chemical sciences. Papers that consider multiple scales, from the laboratory up to and including plant scale, are particularly encouraged.
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