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Nanomaterials with oxygen mobility for catalysts of biofuels transformation into syngas, SOFC and oxygen/hydrogen separation membranes: Design and performance. / Sadykov, V.; Eremeev, N.; Sadovskaya, E. et al.

In: Catalysis Today, Vol. 423, 113936, 01.11.2023.

Research output: Contribution to journalArticlepeer-review

Harvard

Sadykov, V, Eremeev, N, Sadovskaya, E, Bespalko, Y, Simonov, M, Arapova, M & Smal, E 2023, 'Nanomaterials with oxygen mobility for catalysts of biofuels transformation into syngas, SOFC and oxygen/hydrogen separation membranes: Design and performance', Catalysis Today, vol. 423, 113936. https://doi.org/10.1016/j.cattod.2022.10.018

APA

Sadykov, V., Eremeev, N., Sadovskaya, E., Bespalko, Y., Simonov, M., Arapova, M., & Smal, E. (2023). Nanomaterials with oxygen mobility for catalysts of biofuels transformation into syngas, SOFC and oxygen/hydrogen separation membranes: Design and performance. Catalysis Today, 423, [113936]. https://doi.org/10.1016/j.cattod.2022.10.018

Vancouver

Sadykov V, Eremeev N, Sadovskaya E, Bespalko Y, Simonov M, Arapova M et al. Nanomaterials with oxygen mobility for catalysts of biofuels transformation into syngas, SOFC and oxygen/hydrogen separation membranes: Design and performance. Catalysis Today. 2023 Nov 1;423:113936. Epub 2022 Oct 28. doi: 10.1016/j.cattod.2022.10.018

Author

Sadykov, V. ; Eremeev, N. ; Sadovskaya, E. et al. / Nanomaterials with oxygen mobility for catalysts of biofuels transformation into syngas, SOFC and oxygen/hydrogen separation membranes: Design and performance. In: Catalysis Today. 2023 ; Vol. 423.

BibTeX

@article{dbaa5c4f2a814ba59cb0f9bea2e186e7,
title = "Nanomaterials with oxygen mobility for catalysts of biofuels transformation into syngas, SOFC and oxygen/hydrogen separation membranes: Design and performance",
abstract = "Modern hydrogen energy technologies include generation of syngas and pure hydrogen from biofuels to be used for green energy production in solid oxide fuel cells (SOFC). To be economically feasible, these processes require design of stable, efficient and inexpensive catalysts, permselective membranes for hydrogen and oxygen separation as well as SOFC cathode and anode materials. In all cases, such materials should possess a high oxygen mobility. This review presents results of our research devoted to design of materials based on complex oxides with fluorite, perovskite, and spinel structures used in these applications. The key aspect is characterization of their oxygen mobility by unique method of temperature –programmed oxygen heteroexchange in flow reactors and finding its dependence on their composition, real structure/microstructure and surface properties affected by methods of synthesis and elucidated with the help of modern structural, spectroscopic and kinetic methods. Optimized materials were shown to provide stable and efficient performance in catalytic reactors, membranes and solid oxide fuels cells.",
keywords = "Biofuels reforming, Characterization, Fluorites, Hydrogen and oxygen separation membranes, Hydrogen and syngas, Nanocomposites, Oxygen isotope heteroexchange, Oxygen mobility, Performance, Perovskites, Solid oxide fuel cells, Spinel, Structured catalysts, Synthesis",
author = "V. Sadykov and N. Eremeev and E. Sadovskaya and Y. Bespalko and M. Simonov and M. Arapova and E. Smal",
note = "Funding Information: Authors are glad to acknowledge efficient collaboration on this thematics in frames of a lot of international projects. Design and studies of structured catalysts continue in frames of the budget project AAA-A21–121011390007-7 of Boreskov Institute of catalysis. Publisher Copyright: {\textcopyright} 2022 Elsevier B.V.",
year = "2023",
month = nov,
day = "1",
doi = "10.1016/j.cattod.2022.10.018",
language = "English",
volume = "423",
journal = "Catalysis Today",
issn = "0920-5861",
publisher = "Elsevier",

}

RIS

TY - JOUR

T1 - Nanomaterials with oxygen mobility for catalysts of biofuels transformation into syngas, SOFC and oxygen/hydrogen separation membranes: Design and performance

AU - Sadykov, V.

AU - Eremeev, N.

AU - Sadovskaya, E.

AU - Bespalko, Y.

AU - Simonov, M.

AU - Arapova, M.

AU - Smal, E.

N1 - Funding Information: Authors are glad to acknowledge efficient collaboration on this thematics in frames of a lot of international projects. Design and studies of structured catalysts continue in frames of the budget project AAA-A21–121011390007-7 of Boreskov Institute of catalysis. Publisher Copyright: © 2022 Elsevier B.V.

PY - 2023/11/1

Y1 - 2023/11/1

N2 - Modern hydrogen energy technologies include generation of syngas and pure hydrogen from biofuels to be used for green energy production in solid oxide fuel cells (SOFC). To be economically feasible, these processes require design of stable, efficient and inexpensive catalysts, permselective membranes for hydrogen and oxygen separation as well as SOFC cathode and anode materials. In all cases, such materials should possess a high oxygen mobility. This review presents results of our research devoted to design of materials based on complex oxides with fluorite, perovskite, and spinel structures used in these applications. The key aspect is characterization of their oxygen mobility by unique method of temperature –programmed oxygen heteroexchange in flow reactors and finding its dependence on their composition, real structure/microstructure and surface properties affected by methods of synthesis and elucidated with the help of modern structural, spectroscopic and kinetic methods. Optimized materials were shown to provide stable and efficient performance in catalytic reactors, membranes and solid oxide fuels cells.

AB - Modern hydrogen energy technologies include generation of syngas and pure hydrogen from biofuels to be used for green energy production in solid oxide fuel cells (SOFC). To be economically feasible, these processes require design of stable, efficient and inexpensive catalysts, permselective membranes for hydrogen and oxygen separation as well as SOFC cathode and anode materials. In all cases, such materials should possess a high oxygen mobility. This review presents results of our research devoted to design of materials based on complex oxides with fluorite, perovskite, and spinel structures used in these applications. The key aspect is characterization of their oxygen mobility by unique method of temperature –programmed oxygen heteroexchange in flow reactors and finding its dependence on their composition, real structure/microstructure and surface properties affected by methods of synthesis and elucidated with the help of modern structural, spectroscopic and kinetic methods. Optimized materials were shown to provide stable and efficient performance in catalytic reactors, membranes and solid oxide fuels cells.

KW - Biofuels reforming

KW - Characterization

KW - Fluorites

KW - Hydrogen and oxygen separation membranes

KW - Hydrogen and syngas

KW - Nanocomposites

KW - Oxygen isotope heteroexchange

KW - Oxygen mobility

KW - Performance

KW - Perovskites

KW - Solid oxide fuel cells

KW - Spinel

KW - Structured catalysts

KW - Synthesis

UR - http://www.scopus.com/inward/record.url?scp=85141263082&partnerID=8YFLogxK

UR - https://www.mendeley.com/catalogue/1473ac98-86d6-3a6c-a817-b0f0aec60119/

U2 - 10.1016/j.cattod.2022.10.018

DO - 10.1016/j.cattod.2022.10.018

M3 - Article

AN - SCOPUS:85141263082

VL - 423

JO - Catalysis Today

JF - Catalysis Today

SN - 0920-5861

M1 - 113936

ER -

ID: 39334715