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Design of Catalytic Polyfunctional Nanomaterials for the Hydrogen Production Processes. / Potemkin, D. I.; Snytnikov, P. V.; Badmaev, S. D. et al.

In: Nanotechnologies in Russia, Vol. 15, No. 3-6, 05.2020, p. 308-313.

Research output: Contribution to journalArticlepeer-review

Harvard

Potemkin, DI, Snytnikov, PV, Badmaev, SD, Uskov, SI, Gorlova, AM, Rogozhnikov, VN, Pechenkin, AA, Kulikov, AV, Shilov, VA, Ruban, NV, Belyaev, VD & Sobyanin, VA 2020, 'Design of Catalytic Polyfunctional Nanomaterials for the Hydrogen Production Processes', Nanotechnologies in Russia, vol. 15, no. 3-6, pp. 308-313. https://doi.org/10.1134/S1995078020030106

APA

Potemkin, D. I., Snytnikov, P. V., Badmaev, S. D., Uskov, S. I., Gorlova, A. M., Rogozhnikov, V. N., Pechenkin, A. A., Kulikov, A. V., Shilov, V. A., Ruban, N. V., Belyaev, V. D., & Sobyanin, V. A. (2020). Design of Catalytic Polyfunctional Nanomaterials for the Hydrogen Production Processes. Nanotechnologies in Russia, 15(3-6), 308-313. https://doi.org/10.1134/S1995078020030106

Vancouver

Potemkin DI, Snytnikov PV, Badmaev SD, Uskov SI, Gorlova AM, Rogozhnikov VN et al. Design of Catalytic Polyfunctional Nanomaterials for the Hydrogen Production Processes. Nanotechnologies in Russia. 2020 May;15(3-6):308-313. doi: 10.1134/S1995078020030106

Author

Potemkin, D. I. ; Snytnikov, P. V. ; Badmaev, S. D. et al. / Design of Catalytic Polyfunctional Nanomaterials for the Hydrogen Production Processes. In: Nanotechnologies in Russia. 2020 ; Vol. 15, No. 3-6. pp. 308-313.

BibTeX

@article{3c51f94f477f4249be5b37a876761b9f,
title = "Design of Catalytic Polyfunctional Nanomaterials for the Hydrogen Production Processes",
abstract = "The processes of hydrogen production from various types of fossil and renewable fuels are energy-intensive multi-route chemical reactions, and for their efficient implementation it is necessary to use selective and high-performance catalysts that combine high activity, thermal conductivity, and corrosion and thermal resistance. A general strategy for the design of catalytic systems for hydrogen production is outlined; it consists in the use of composite catalysts of the “metal nanoparticles/active oxide nanoparticles/structural oxide component/structured metal support” type; an approach for their directed synthesis is described. The structured metal support provides efficient heat removal or supply for exo- or endothermic reactions, possesses good hydrodynamic characteristics, and facilitates scale transition. The structural oxide component (aluminum oxide) provides thermal and corrosion resistance and a high specific surface area of the catalytic coating, as well as performing a protective function for the metal support. The active oxide component (mainly cerium–zirconium oxides) increases resistance to carbonization due to oxygen mobility and maintains a high dispersion of the active component due to its strong metal–support interaction. Metal nanoparticles 1–2 nm in size are involved in the activation of substrate molecules. FeCrAl alloy wire meshes, formed into cylindrical blocks of specified sizes, to be used as a heat-conducting substrate. By controlled annealing with the formation of a micron α-Al2O3 layer and subsequent deposition of a η-Al2O3 layer according to the Bayer method (through aluminum hydroxide), a structural layer of η-Al2O3 with a “breathing” needle morphology was deposited onto the FeCrAl alloy surface; then the catalytic active component was deposited onto this layer by impregnation and/or deposition. The efficiency of the proposed strategy is shown for Rh/Ce0.75Zr0.25O2 – δ–η-Al2O3/FeCrAl catalysts for methane tri-reforming and Cu–CeO2 – δ/η-Al2O3/FeCrAl catalysts for dimethoxymethane steam reforming.",
keywords = "CHALLENGES, CONVERSION, METHANOL, GAS",
author = "Potemkin, {D. I.} and Snytnikov, {P. V.} and Badmaev, {S. D.} and Uskov, {S. I.} and Gorlova, {A. M.} and Rogozhnikov, {V. N.} and Pechenkin, {A. A.} and Kulikov, {A. V.} and Shilov, {V. A.} and Ruban, {N. V.} and Belyaev, {V. D.} and Sobyanin, {V. A.}",
note = "Funding Information: The work was financially supported by the Russian Foundation for Basic Research in the framework of project no. 19-33-60008 (D.I. Potemkin) for the study of the tri-reforming of methane. Publisher Copyright: {\textcopyright} 2020, Pleiades Publishing, Ltd. Copyright: Copyright 2020 Elsevier B.V., All rights reserved.",
year = "2020",
month = may,
doi = "10.1134/S1995078020030106",
language = "English",
volume = "15",
pages = "308--313",
journal = "Nanotechnologies in Russia",
issn = "1995-0780",
publisher = "Maik Nauka Publishing / Springer SBM",
number = "3-6",

}

RIS

TY - JOUR

T1 - Design of Catalytic Polyfunctional Nanomaterials for the Hydrogen Production Processes

AU - Potemkin, D. I.

AU - Snytnikov, P. V.

AU - Badmaev, S. D.

AU - Uskov, S. I.

AU - Gorlova, A. M.

AU - Rogozhnikov, V. N.

AU - Pechenkin, A. A.

AU - Kulikov, A. V.

AU - Shilov, V. A.

AU - Ruban, N. V.

AU - Belyaev, V. D.

AU - Sobyanin, V. A.

N1 - Funding Information: The work was financially supported by the Russian Foundation for Basic Research in the framework of project no. 19-33-60008 (D.I. Potemkin) for the study of the tri-reforming of methane. Publisher Copyright: © 2020, Pleiades Publishing, Ltd. Copyright: Copyright 2020 Elsevier B.V., All rights reserved.

PY - 2020/5

Y1 - 2020/5

N2 - The processes of hydrogen production from various types of fossil and renewable fuels are energy-intensive multi-route chemical reactions, and for their efficient implementation it is necessary to use selective and high-performance catalysts that combine high activity, thermal conductivity, and corrosion and thermal resistance. A general strategy for the design of catalytic systems for hydrogen production is outlined; it consists in the use of composite catalysts of the “metal nanoparticles/active oxide nanoparticles/structural oxide component/structured metal support” type; an approach for their directed synthesis is described. The structured metal support provides efficient heat removal or supply for exo- or endothermic reactions, possesses good hydrodynamic characteristics, and facilitates scale transition. The structural oxide component (aluminum oxide) provides thermal and corrosion resistance and a high specific surface area of the catalytic coating, as well as performing a protective function for the metal support. The active oxide component (mainly cerium–zirconium oxides) increases resistance to carbonization due to oxygen mobility and maintains a high dispersion of the active component due to its strong metal–support interaction. Metal nanoparticles 1–2 nm in size are involved in the activation of substrate molecules. FeCrAl alloy wire meshes, formed into cylindrical blocks of specified sizes, to be used as a heat-conducting substrate. By controlled annealing with the formation of a micron α-Al2O3 layer and subsequent deposition of a η-Al2O3 layer according to the Bayer method (through aluminum hydroxide), a structural layer of η-Al2O3 with a “breathing” needle morphology was deposited onto the FeCrAl alloy surface; then the catalytic active component was deposited onto this layer by impregnation and/or deposition. The efficiency of the proposed strategy is shown for Rh/Ce0.75Zr0.25O2 – δ–η-Al2O3/FeCrAl catalysts for methane tri-reforming and Cu–CeO2 – δ/η-Al2O3/FeCrAl catalysts for dimethoxymethane steam reforming.

AB - The processes of hydrogen production from various types of fossil and renewable fuels are energy-intensive multi-route chemical reactions, and for their efficient implementation it is necessary to use selective and high-performance catalysts that combine high activity, thermal conductivity, and corrosion and thermal resistance. A general strategy for the design of catalytic systems for hydrogen production is outlined; it consists in the use of composite catalysts of the “metal nanoparticles/active oxide nanoparticles/structural oxide component/structured metal support” type; an approach for their directed synthesis is described. The structured metal support provides efficient heat removal or supply for exo- or endothermic reactions, possesses good hydrodynamic characteristics, and facilitates scale transition. The structural oxide component (aluminum oxide) provides thermal and corrosion resistance and a high specific surface area of the catalytic coating, as well as performing a protective function for the metal support. The active oxide component (mainly cerium–zirconium oxides) increases resistance to carbonization due to oxygen mobility and maintains a high dispersion of the active component due to its strong metal–support interaction. Metal nanoparticles 1–2 nm in size are involved in the activation of substrate molecules. FeCrAl alloy wire meshes, formed into cylindrical blocks of specified sizes, to be used as a heat-conducting substrate. By controlled annealing with the formation of a micron α-Al2O3 layer and subsequent deposition of a η-Al2O3 layer according to the Bayer method (through aluminum hydroxide), a structural layer of η-Al2O3 with a “breathing” needle morphology was deposited onto the FeCrAl alloy surface; then the catalytic active component was deposited onto this layer by impregnation and/or deposition. The efficiency of the proposed strategy is shown for Rh/Ce0.75Zr0.25O2 – δ–η-Al2O3/FeCrAl catalysts for methane tri-reforming and Cu–CeO2 – δ/η-Al2O3/FeCrAl catalysts for dimethoxymethane steam reforming.

KW - CHALLENGES

KW - CONVERSION

KW - METHANOL

KW - GAS

UR - http://www.scopus.com/inward/record.url?scp=85098241092&partnerID=8YFLogxK

U2 - 10.1134/S1995078020030106

DO - 10.1134/S1995078020030106

M3 - Article

AN - SCOPUS:85098241092

VL - 15

SP - 308

EP - 313

JO - Nanotechnologies in Russia

JF - Nanotechnologies in Russia

SN - 1995-0780

IS - 3-6

ER -

ID: 27342405