Standard

Kinetic features of the deep oxidation of propane over a Pt/fiberglass catalyst. / Sadovskaya, Ekaterina M.; Kovalyov, Evgenii V.; Bal'zhinimaev, Bair S.

в: Chemical Engineering Journal, Том 349, 01.10.2018, стр. 547-553.

Результаты исследований: Научные публикации в периодических изданияхстатьяРецензирование

Harvard

Sadovskaya, EM, Kovalyov, EV & Bal'zhinimaev, BS 2018, 'Kinetic features of the deep oxidation of propane over a Pt/fiberglass catalyst', Chemical Engineering Journal, Том. 349, стр. 547-553. https://doi.org/10.1016/j.cej.2018.05.103

APA

Sadovskaya, E. M., Kovalyov, E. V., & Bal'zhinimaev, B. S. (2018). Kinetic features of the deep oxidation of propane over a Pt/fiberglass catalyst. Chemical Engineering Journal, 349, 547-553. https://doi.org/10.1016/j.cej.2018.05.103

Vancouver

Sadovskaya EM, Kovalyov EV, Bal'zhinimaev BS. Kinetic features of the deep oxidation of propane over a Pt/fiberglass catalyst. Chemical Engineering Journal. 2018 окт. 1;349:547-553. doi: 10.1016/j.cej.2018.05.103

Author

Sadovskaya, Ekaterina M. ; Kovalyov, Evgenii V. ; Bal'zhinimaev, Bair S. / Kinetic features of the deep oxidation of propane over a Pt/fiberglass catalyst. в: Chemical Engineering Journal. 2018 ; Том 349. стр. 547-553.

BibTeX

@article{78fc9fa8d66549139b1354d11ab12c34,
title = "Kinetic features of the deep oxidation of propane over a Pt/fiberglass catalyst",
abstract = "A detailed kinetic study on the deep oxidation of propane was carried out in a wide range of temperatures and concentrations using a novel Pt-fiberglass catalyst. Highly dispersed 1–1.5 nm Pt2+-Pt0 metal-oxide clusters are confined in the bulk of glass at a depth up to 20 nm. In spite of extremely low platinum content (0.01–0.02%), this catalyst showed a very high activity in the propane oxidation. The modified Langmuir-Hinshelwood mechanism including reversible adsorption of molecular oxygen and irreversible adsorption of propane and its subsequent combustion by adjacent oxygens was proposed. The simplest kinetic model adequately describing such experimental features like the extremal dependence of the reaction rate on the O2 concentrations, the sharp changes of reaction order with respect to oxygen, the significant growth of apparent activation energy with decreasing the oxygen concentration, etc. was developed. In particular, the extremal dependence is caused by competitive adsorption of propane and oxygen on the different active sites. At high O2 concentrations, the adsorbed oxygen occupies virtually all active sites that are accessible for propane adsorption, and the reaction rate sharply decreases. In the case of oxygen deficiency, the adsorbed propane does not occupy completely the active sites for oxygen adsorption, so that the reaction rate increases with propane concentration. The maximum reaction rate is attained at the defined O2/C3H8 ratios when the concentrations of adsorbed oxygen and propane are comparable.",
keywords = "Fiberglass, Kinetics, Langmuir-Hinshelwood, Platinum clusters, Propane oxidation",
author = "Sadovskaya, {Ekaterina M.} and Kovalyov, {Evgenii V.} and Bal'zhinimaev, {Bair S.}",
year = "2018",
month = oct,
day = "1",
doi = "10.1016/j.cej.2018.05.103",
language = "English",
volume = "349",
pages = "547--553",
journal = "Chemical Engineering Journal",
issn = "1385-8947",
publisher = "Elsevier",

}

RIS

TY - JOUR

T1 - Kinetic features of the deep oxidation of propane over a Pt/fiberglass catalyst

AU - Sadovskaya, Ekaterina M.

AU - Kovalyov, Evgenii V.

AU - Bal'zhinimaev, Bair S.

PY - 2018/10/1

Y1 - 2018/10/1

N2 - A detailed kinetic study on the deep oxidation of propane was carried out in a wide range of temperatures and concentrations using a novel Pt-fiberglass catalyst. Highly dispersed 1–1.5 nm Pt2+-Pt0 metal-oxide clusters are confined in the bulk of glass at a depth up to 20 nm. In spite of extremely low platinum content (0.01–0.02%), this catalyst showed a very high activity in the propane oxidation. The modified Langmuir-Hinshelwood mechanism including reversible adsorption of molecular oxygen and irreversible adsorption of propane and its subsequent combustion by adjacent oxygens was proposed. The simplest kinetic model adequately describing such experimental features like the extremal dependence of the reaction rate on the O2 concentrations, the sharp changes of reaction order with respect to oxygen, the significant growth of apparent activation energy with decreasing the oxygen concentration, etc. was developed. In particular, the extremal dependence is caused by competitive adsorption of propane and oxygen on the different active sites. At high O2 concentrations, the adsorbed oxygen occupies virtually all active sites that are accessible for propane adsorption, and the reaction rate sharply decreases. In the case of oxygen deficiency, the adsorbed propane does not occupy completely the active sites for oxygen adsorption, so that the reaction rate increases with propane concentration. The maximum reaction rate is attained at the defined O2/C3H8 ratios when the concentrations of adsorbed oxygen and propane are comparable.

AB - A detailed kinetic study on the deep oxidation of propane was carried out in a wide range of temperatures and concentrations using a novel Pt-fiberglass catalyst. Highly dispersed 1–1.5 nm Pt2+-Pt0 metal-oxide clusters are confined in the bulk of glass at a depth up to 20 nm. In spite of extremely low platinum content (0.01–0.02%), this catalyst showed a very high activity in the propane oxidation. The modified Langmuir-Hinshelwood mechanism including reversible adsorption of molecular oxygen and irreversible adsorption of propane and its subsequent combustion by adjacent oxygens was proposed. The simplest kinetic model adequately describing such experimental features like the extremal dependence of the reaction rate on the O2 concentrations, the sharp changes of reaction order with respect to oxygen, the significant growth of apparent activation energy with decreasing the oxygen concentration, etc. was developed. In particular, the extremal dependence is caused by competitive adsorption of propane and oxygen on the different active sites. At high O2 concentrations, the adsorbed oxygen occupies virtually all active sites that are accessible for propane adsorption, and the reaction rate sharply decreases. In the case of oxygen deficiency, the adsorbed propane does not occupy completely the active sites for oxygen adsorption, so that the reaction rate increases with propane concentration. The maximum reaction rate is attained at the defined O2/C3H8 ratios when the concentrations of adsorbed oxygen and propane are comparable.

KW - Fiberglass

KW - Kinetics

KW - Langmuir-Hinshelwood

KW - Platinum clusters

KW - Propane oxidation

UR - http://www.scopus.com/inward/record.url?scp=85047631791&partnerID=8YFLogxK

U2 - 10.1016/j.cej.2018.05.103

DO - 10.1016/j.cej.2018.05.103

M3 - Article

AN - SCOPUS:85047631791

VL - 349

SP - 547

EP - 553

JO - Chemical Engineering Journal

JF - Chemical Engineering Journal

SN - 1385-8947

ER -

ID: 23008458