Mechanism and Kinetic Study of Reducing MoO(3) to MoO(2) with CO–15 vol % CO(2) Mixed Gases

[Image: see text] In the present paper, the reduction reaction of high-purity MoO(3) with CO–15 vol % CO(2) mixed gases in the temperature range of 901–948 K is investigated via the thermogravimetric analysis technology. The results show that reduction of MoO(3) to MoO(2) follows a three-step reacti...

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Autores principales: Wang, Lu, Xue, Zheng-Liang, Huang, Ao, Wang, Fang-Fang
Formato: Online Artículo Texto
Lenguaje:English
Publicado: American Chemical Society 2019
Acceso en línea:https://www.ncbi.nlm.nih.gov/pmc/articles/PMC6882118/
https://www.ncbi.nlm.nih.gov/pubmed/31788638
http://dx.doi.org/10.1021/acsomega.9b03171
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author Wang, Lu
Xue, Zheng-Liang
Huang, Ao
Wang, Fang-Fang
author_facet Wang, Lu
Xue, Zheng-Liang
Huang, Ao
Wang, Fang-Fang
author_sort Wang, Lu
collection PubMed
description [Image: see text] In the present paper, the reduction reaction of high-purity MoO(3) with CO–15 vol % CO(2) mixed gases in the temperature range of 901–948 K is investigated via the thermogravimetric analysis technology. The results show that reduction of MoO(3) to MoO(2) follows a three-step reaction process, viz., MoO(3) is first reduced into Mo(9)O(26), followed by Mo(4)O(11), and finally to MoO(2). The reaction sequences of MoO(3) → Mo(9)O(26) → Mo(4)O(11) → MoO(2) are proposed, which are quite different from those observed on reduction of MoO(3) by pure H(2) or CO gases. Pure Mo(9)O(26) and Mo(4)O(11) could be synthesized once suitable time was controlled. Rate-controlling steps for the reduction from MoO(3) to Mo(9)O(26) and Mo(9)O(26) to MoO(2) (include both Mo(9)O(26) to Mo(4)O(11) and Mo(4)O(11) to MoO(2)) are interfacial chemical reactions, with the activation energies of 318.326 and 112.047 kJ/mol, respectively. This study also discovers that the as-synthesized MoO(2) keeps the same platelet-shaped and smooth morphology as the MoO(3) raw material; however, its particles size gradually increased as the reaction proceeds due to the formation of low-melting-point eutectic and the sticking of different particles.
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spelling pubmed-68821182019-11-29 Mechanism and Kinetic Study of Reducing MoO(3) to MoO(2) with CO–15 vol % CO(2) Mixed Gases Wang, Lu Xue, Zheng-Liang Huang, Ao Wang, Fang-Fang ACS Omega [Image: see text] In the present paper, the reduction reaction of high-purity MoO(3) with CO–15 vol % CO(2) mixed gases in the temperature range of 901–948 K is investigated via the thermogravimetric analysis technology. The results show that reduction of MoO(3) to MoO(2) follows a three-step reaction process, viz., MoO(3) is first reduced into Mo(9)O(26), followed by Mo(4)O(11), and finally to MoO(2). The reaction sequences of MoO(3) → Mo(9)O(26) → Mo(4)O(11) → MoO(2) are proposed, which are quite different from those observed on reduction of MoO(3) by pure H(2) or CO gases. Pure Mo(9)O(26) and Mo(4)O(11) could be synthesized once suitable time was controlled. Rate-controlling steps for the reduction from MoO(3) to Mo(9)O(26) and Mo(9)O(26) to MoO(2) (include both Mo(9)O(26) to Mo(4)O(11) and Mo(4)O(11) to MoO(2)) are interfacial chemical reactions, with the activation energies of 318.326 and 112.047 kJ/mol, respectively. This study also discovers that the as-synthesized MoO(2) keeps the same platelet-shaped and smooth morphology as the MoO(3) raw material; however, its particles size gradually increased as the reaction proceeds due to the formation of low-melting-point eutectic and the sticking of different particles. American Chemical Society 2019-11-15 /pmc/articles/PMC6882118/ /pubmed/31788638 http://dx.doi.org/10.1021/acsomega.9b03171 Text en Copyright © 2019 American Chemical Society This is an open access article published under an ACS AuthorChoice License (http://pubs.acs.org/page/policy/authorchoice_termsofuse.html) , which permits copying and redistribution of the article or any adaptations for non-commercial purposes.
spellingShingle Wang, Lu
Xue, Zheng-Liang
Huang, Ao
Wang, Fang-Fang
Mechanism and Kinetic Study of Reducing MoO(3) to MoO(2) with CO–15 vol % CO(2) Mixed Gases
title Mechanism and Kinetic Study of Reducing MoO(3) to MoO(2) with CO–15 vol % CO(2) Mixed Gases
title_full Mechanism and Kinetic Study of Reducing MoO(3) to MoO(2) with CO–15 vol % CO(2) Mixed Gases
title_fullStr Mechanism and Kinetic Study of Reducing MoO(3) to MoO(2) with CO–15 vol % CO(2) Mixed Gases
title_full_unstemmed Mechanism and Kinetic Study of Reducing MoO(3) to MoO(2) with CO–15 vol % CO(2) Mixed Gases
title_short Mechanism and Kinetic Study of Reducing MoO(3) to MoO(2) with CO–15 vol % CO(2) Mixed Gases
title_sort mechanism and kinetic study of reducing moo(3) to moo(2) with co–15 vol % co(2) mixed gases
url https://www.ncbi.nlm.nih.gov/pmc/articles/PMC6882118/
https://www.ncbi.nlm.nih.gov/pubmed/31788638
http://dx.doi.org/10.1021/acsomega.9b03171
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