Standard

Nanocomposite catalysts for transformation of biofuels into syngas and hydrogen : Fundamentals of design and performance, application in structured reactors and catalytic membranes. / Sadykov, V. A.; Arapova, M. V.; Smal, E. A. et al.

Catalysis. ed. / James J. Spivey; Yi-Fan Han; Dushyant Shekhawat. Royal Society of Chemistry, 2019. p. 216-241 (Catalysis; Vol. 31).

Research output: Chapter in Book/Report/Conference proceedingChapterResearchpeer-review

Harvard

Sadykov, VA, Arapova, MV, Smal, EA, Pavlova, SN, Bobrova, LN, Eremeev, NF, Mezentseva, NV & Simonov, MN 2019, Nanocomposite catalysts for transformation of biofuels into syngas and hydrogen: Fundamentals of design and performance, application in structured reactors and catalytic membranes. in JJ Spivey, Y-F Han & D Shekhawat (eds), Catalysis. Catalysis, vol. 31, Royal Society of Chemistry, pp. 216-241. https://doi.org/10.1039/9781788016971-00216

APA

Sadykov, V. A., Arapova, M. V., Smal, E. A., Pavlova, S. N., Bobrova, L. N., Eremeev, N. F., Mezentseva, N. V., & Simonov, M. N. (2019). Nanocomposite catalysts for transformation of biofuels into syngas and hydrogen: Fundamentals of design and performance, application in structured reactors and catalytic membranes. In J. J. Spivey, Y-F. Han, & D. Shekhawat (Eds.), Catalysis (pp. 216-241). (Catalysis; Vol. 31). Royal Society of Chemistry. https://doi.org/10.1039/9781788016971-00216

Vancouver

Sadykov VA, Arapova MV, Smal EA, Pavlova SN, Bobrova LN, Eremeev NF et al. Nanocomposite catalysts for transformation of biofuels into syngas and hydrogen: Fundamentals of design and performance, application in structured reactors and catalytic membranes. In Spivey JJ, Han Y-F, Shekhawat D, editors, Catalysis. Royal Society of Chemistry. 2019. p. 216-241. (Catalysis). doi: 10.1039/9781788016971-00216

Author

Sadykov, V. A. ; Arapova, M. V. ; Smal, E. A. et al. / Nanocomposite catalysts for transformation of biofuels into syngas and hydrogen : Fundamentals of design and performance, application in structured reactors and catalytic membranes. Catalysis. editor / James J. Spivey ; Yi-Fan Han ; Dushyant Shekhawat. Royal Society of Chemistry, 2019. pp. 216-241 (Catalysis).

BibTeX

@inbook{e8b704fb8ba24f148e8428ee1cca0c3b,
title = "Nanocomposite catalysts for transformation of biofuels into syngas and hydrogen: Fundamentals of design and performance, application in structured reactors and catalytic membranes",
abstract = "In this review problems related to design and performance of stable and efficient catalysts of biogas/biofuels transformation into syngas and hydrogen based on nanocrystalline oxides with fluorite, perovskite and spinel oxides and their nanocomposites promoted by nanoparticles of Pt group metals and Ni-based alloys are considered. Tailor-made design of these catalysts is based upon elucidation of the relationships between their synthesis procedure, composition, real structure/microstructure, surface properties, oxygen mobility and reactivity determined in a great extent by the metal-support interaction, which requires application of modern sophisticated structural, spectroscopic, kinetic (including in situ FTIRS and isotope transients) methods and mathematical modeling. Thin layers of these optimized catalysts supported on structured heat-conducting substrates, asymmetric supported oxygen or hydrogen separation membranes demonstrated high and stable performance in transformation of biogas and biofuels into syngas and hydrogen.",
author = "Sadykov, {V. A.} and Arapova, {M. V.} and Smal, {E. A.} and Pavlova, {S. N.} and Bobrova, {L. N.} and Eremeev, {N. F.} and Mezentseva, {N. V.} and Simonov, {M. N.}",
year = "2019",
month = jan,
day = "1",
doi = "10.1039/9781788016971-00216",
language = "English",
series = "Catalysis",
publisher = "Royal Society of Chemistry",
pages = "216--241",
editor = "Spivey, {James J.} and Yi-Fan Han and Dushyant Shekhawat",
booktitle = "Catalysis",
address = "United Kingdom",

}

RIS

TY - CHAP

T1 - Nanocomposite catalysts for transformation of biofuels into syngas and hydrogen

T2 - Fundamentals of design and performance, application in structured reactors and catalytic membranes

AU - Sadykov, V. A.

AU - Arapova, M. V.

AU - Smal, E. A.

AU - Pavlova, S. N.

AU - Bobrova, L. N.

AU - Eremeev, N. F.

AU - Mezentseva, N. V.

AU - Simonov, M. N.

PY - 2019/1/1

Y1 - 2019/1/1

N2 - In this review problems related to design and performance of stable and efficient catalysts of biogas/biofuels transformation into syngas and hydrogen based on nanocrystalline oxides with fluorite, perovskite and spinel oxides and their nanocomposites promoted by nanoparticles of Pt group metals and Ni-based alloys are considered. Tailor-made design of these catalysts is based upon elucidation of the relationships between their synthesis procedure, composition, real structure/microstructure, surface properties, oxygen mobility and reactivity determined in a great extent by the metal-support interaction, which requires application of modern sophisticated structural, spectroscopic, kinetic (including in situ FTIRS and isotope transients) methods and mathematical modeling. Thin layers of these optimized catalysts supported on structured heat-conducting substrates, asymmetric supported oxygen or hydrogen separation membranes demonstrated high and stable performance in transformation of biogas and biofuels into syngas and hydrogen.

AB - In this review problems related to design and performance of stable and efficient catalysts of biogas/biofuels transformation into syngas and hydrogen based on nanocrystalline oxides with fluorite, perovskite and spinel oxides and their nanocomposites promoted by nanoparticles of Pt group metals and Ni-based alloys are considered. Tailor-made design of these catalysts is based upon elucidation of the relationships between their synthesis procedure, composition, real structure/microstructure, surface properties, oxygen mobility and reactivity determined in a great extent by the metal-support interaction, which requires application of modern sophisticated structural, spectroscopic, kinetic (including in situ FTIRS and isotope transients) methods and mathematical modeling. Thin layers of these optimized catalysts supported on structured heat-conducting substrates, asymmetric supported oxygen or hydrogen separation membranes demonstrated high and stable performance in transformation of biogas and biofuels into syngas and hydrogen.

UR - http://www.scopus.com/inward/record.url?scp=85062423611&partnerID=8YFLogxK

U2 - 10.1039/9781788016971-00216

DO - 10.1039/9781788016971-00216

M3 - Chapter

AN - SCOPUS:85062423611

T3 - Catalysis

SP - 216

EP - 241

BT - Catalysis

A2 - Spivey, James J.

A2 - Han, Yi-Fan

A2 - Shekhawat, Dushyant

PB - Royal Society of Chemistry

ER -

ID: 18678139