A review of C(1) chemistry synthesis using yttrium-stabilized zirconia catalyst

Authors
Indarto, AntoniusChoi, Jae-WookLee, HwaungSong, Hyung Keun
Issue Date
2008-02
Publisher
ELSEVIER SCIENCE BV
Citation
JOURNAL OF RARE EARTHS, v.26, no.1, pp.1 - 6
Abstract
C(1) chemistry based on synthesis gas, methane, and carbon dioxide offers many routes to industrial chemicals. The reactions related to the synthesis of gas can be classified into direct and indirect approach for making such products, such as acetic acid, dimethyl ether, and alcohol. Catalytic syngas processing is currently done at high temperatures and pressures, conditions that could be unfavorable for the life of the catalyst. Another issue of C, chemistry is related to the methane-initiated process. It has been known that direct methane conversions are still suffering from low yields and selectivity of products resulting in unprofitable ways to produce products, such as higher hydrocarbons, methanol, and so on. However, many experts and researchers are still trying to find the best method to overcome these barriers, for example, by finding the best catalyst to reduce the high-energy barrier of the reactions and conduct only selective catalyst-surface reactions. The application of Yttria-Stabilized Zirconia (YSZ) and its combination with other metals for catalyzing purposes are increasing. The existence of an interesting site that acts as oxygen store could be the main reason for it. Moreover, formation of intermediate species on the surface of YSZ also contributes significantly in increasing the production of some specific products. Understanding the phenomena happening inside could be necessary. In this article, the use of YSZ for some C, chemistry reactions was discussed and reviewed.
Keywords
COPPER-OXIDE CATALYST; CARBON-DIOXIDE; SYNTHESIS GAS; PARTIAL OXIDATION; OXYGEN VACANCY; METHANOL FORMATION; SUPPORTED RHODIUM; CRYSTALLITE SIZE; CO OXIDATION; MECHANISM; COPPER-OXIDE CATALYST; CARBON-DIOXIDE; SYNTHESIS GAS; PARTIAL OXIDATION; OXYGEN VACANCY; METHANOL FORMATION; SUPPORTED RHODIUM; CRYSTALLITE SIZE; CO OXIDATION; MECHANISM; C(1) chemistry; methane; synthesis gas; methanol; yttria-stabilized zirconia; catalyst; oxygen storage; rare earths
ISSN
1002-0721
URI
https://pubs.kist.re.kr/handle/201004/133780
DOI
10.1016/S1002-0721(08)60026-5
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KIST Article > 2008
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