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Copper-chromite glass fiber catalyst and its performance in the test reaction of deep oxidation of toluene in air. / Zazhigalov, Sergey; Elyshev, Andrey; Lopatin, Sergey et al.

In: Reaction Kinetics, Mechanisms and Catalysis, Vol. 120, No. 1, 02.2017, p. 247-260.

Research output: Contribution to journalArticlepeer-review

Harvard

Zazhigalov, S, Elyshev, A, Lopatin, S, Larina, T, Cherepanova, S, Mikenin, P, Pisarev, D, Baranov, D & Zagoruiko, A 2017, 'Copper-chromite glass fiber catalyst and its performance in the test reaction of deep oxidation of toluene in air', Reaction Kinetics, Mechanisms and Catalysis, vol. 120, no. 1, pp. 247-260. https://doi.org/10.1007/s11144-016-1089-3

APA

Zazhigalov, S., Elyshev, A., Lopatin, S., Larina, T., Cherepanova, S., Mikenin, P., Pisarev, D., Baranov, D., & Zagoruiko, A. (2017). Copper-chromite glass fiber catalyst and its performance in the test reaction of deep oxidation of toluene in air. Reaction Kinetics, Mechanisms and Catalysis, 120(1), 247-260. https://doi.org/10.1007/s11144-016-1089-3

Vancouver

Zazhigalov S, Elyshev A, Lopatin S, Larina T, Cherepanova S, Mikenin P et al. Copper-chromite glass fiber catalyst and its performance in the test reaction of deep oxidation of toluene in air. Reaction Kinetics, Mechanisms and Catalysis. 2017 Feb;120(1):247-260. doi: 10.1007/s11144-016-1089-3

Author

Zazhigalov, Sergey ; Elyshev, Andrey ; Lopatin, Sergey et al. / Copper-chromite glass fiber catalyst and its performance in the test reaction of deep oxidation of toluene in air. In: Reaction Kinetics, Mechanisms and Catalysis. 2017 ; Vol. 120, No. 1. pp. 247-260.

BibTeX

@article{13a38eb2dcac40ac9407d28acc7a2b37,
title = "Copper-chromite glass fiber catalyst and its performance in the test reaction of deep oxidation of toluene in air",
abstract = "The paper is dedicated to the novel glass-fiber catalysts (GFC) using copper chromite as an active component for the reaction of deep oxidation of hydrocarbons and volatile organic compounds (VOCs). The catalyst support is the glass microfibrous fabric preliminarily modified by the addition of an external layer of silica secondary porous support. Surface thermosynthesis was applied for manufacturing of such catalysts. XRD and UV–Vis DRS studies have demonstrated that the active component in the synthesized GFCs is CuCr2O4in the structural type of partially inverted spinel. As shown in experiments with the deep oxidation of toluene in air, the specific activity of CuCr2O4/GFC per unit mass of the active component exceeds that of the similar conventional CuCr2O4/Al2O3catalyst by up to 20–30 times. Such significant rise is explained by both the much more efficient mass transfer in GFC cartridges and the higher intrinsic activity of the copper chromite in the GFC, where the particles of CuCr2O4have the typical size of 10–25 nm compared to >100 nm in case of conventional alumina catalyst. The proposed GFC looks promising for the abatement of hydrocarbons and VOCs in different waste gases.",
keywords = "Copper chromite, Deep oxidation, Glass-fiber catalyst, Toluene, Volatile organic compounds, MIXED OXIDES, SUPPORTS, PLATINUM, COMBUSTION SYNTHESIS, DIESEL SOOT, CO OXIDATION, CLOTH CATALYSTS, OXIDE CATALYST, GAS-PHASE, HYDROGEN-PRODUCTION",
author = "Sergey Zazhigalov and Andrey Elyshev and Sergey Lopatin and Tatyana Larina and Svetlana Cherepanova and Pavel Mikenin and Danil Pisarev and Dmitry Baranov and Andrey Zagoruiko",
year = "2017",
month = feb,
doi = "10.1007/s11144-016-1089-3",
language = "English",
volume = "120",
pages = "247--260",
journal = "Reaction Kinetics, Mechanisms and Catalysis",
issn = "1878-5190",
publisher = "Springer Netherlands",
number = "1",

}

RIS

TY - JOUR

T1 - Copper-chromite glass fiber catalyst and its performance in the test reaction of deep oxidation of toluene in air

AU - Zazhigalov, Sergey

AU - Elyshev, Andrey

AU - Lopatin, Sergey

AU - Larina, Tatyana

AU - Cherepanova, Svetlana

AU - Mikenin, Pavel

AU - Pisarev, Danil

AU - Baranov, Dmitry

AU - Zagoruiko, Andrey

PY - 2017/2

Y1 - 2017/2

N2 - The paper is dedicated to the novel glass-fiber catalysts (GFC) using copper chromite as an active component for the reaction of deep oxidation of hydrocarbons and volatile organic compounds (VOCs). The catalyst support is the glass microfibrous fabric preliminarily modified by the addition of an external layer of silica secondary porous support. Surface thermosynthesis was applied for manufacturing of such catalysts. XRD and UV–Vis DRS studies have demonstrated that the active component in the synthesized GFCs is CuCr2O4in the structural type of partially inverted spinel. As shown in experiments with the deep oxidation of toluene in air, the specific activity of CuCr2O4/GFC per unit mass of the active component exceeds that of the similar conventional CuCr2O4/Al2O3catalyst by up to 20–30 times. Such significant rise is explained by both the much more efficient mass transfer in GFC cartridges and the higher intrinsic activity of the copper chromite in the GFC, where the particles of CuCr2O4have the typical size of 10–25 nm compared to >100 nm in case of conventional alumina catalyst. The proposed GFC looks promising for the abatement of hydrocarbons and VOCs in different waste gases.

AB - The paper is dedicated to the novel glass-fiber catalysts (GFC) using copper chromite as an active component for the reaction of deep oxidation of hydrocarbons and volatile organic compounds (VOCs). The catalyst support is the glass microfibrous fabric preliminarily modified by the addition of an external layer of silica secondary porous support. Surface thermosynthesis was applied for manufacturing of such catalysts. XRD and UV–Vis DRS studies have demonstrated that the active component in the synthesized GFCs is CuCr2O4in the structural type of partially inverted spinel. As shown in experiments with the deep oxidation of toluene in air, the specific activity of CuCr2O4/GFC per unit mass of the active component exceeds that of the similar conventional CuCr2O4/Al2O3catalyst by up to 20–30 times. Such significant rise is explained by both the much more efficient mass transfer in GFC cartridges and the higher intrinsic activity of the copper chromite in the GFC, where the particles of CuCr2O4have the typical size of 10–25 nm compared to >100 nm in case of conventional alumina catalyst. The proposed GFC looks promising for the abatement of hydrocarbons and VOCs in different waste gases.

KW - Copper chromite

KW - Deep oxidation

KW - Glass-fiber catalyst

KW - Toluene

KW - Volatile organic compounds

KW - MIXED OXIDES

KW - SUPPORTS

KW - PLATINUM

KW - COMBUSTION SYNTHESIS

KW - DIESEL SOOT

KW - CO OXIDATION

KW - CLOTH CATALYSTS

KW - OXIDE CATALYST

KW - GAS-PHASE

KW - HYDROGEN-PRODUCTION

UR - http://www.scopus.com/inward/record.url?scp=84991085662&partnerID=8YFLogxK

U2 - 10.1007/s11144-016-1089-3

DO - 10.1007/s11144-016-1089-3

M3 - Article

AN - SCOPUS:84991085662

VL - 120

SP - 247

EP - 260

JO - Reaction Kinetics, Mechanisms and Catalysis

JF - Reaction Kinetics, Mechanisms and Catalysis

SN - 1878-5190

IS - 1

ER -

ID: 10351915