Influence of the calcination temperature on the structure and reducibility of nanoceria obtained from crystalline Ce(OH)CO3 precursor

A high yield green method was developed for the preparation of reactive nanotextured ceria (CeO2). The preparation method is based on the oxidation of a crystalline Ce(OH)CO3 precursor that decompose at relative low temperature (ca. 250 °C) yielding CeO2 nanocrystals initially rich in Ce3+. After in...

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Detalles Bibliográficos
Autores principales: Poggio, E., Jobbágy, M., Moreno, M., Laborde, M., Mariño, F., Baronetti, G.
Formato: JOUR
Materias:
Catalysts
COPROX
Hydrogen purification
Supports
Calcination temperature
Cell contraction
CO-PROX
Differential reactors
Green method
High yield
Low temperatures
Nano-ceria
Nanotextured
Optimum activity
Preparation method
Surface process
Temperature range
Co-prox reactions
Catalyst activity
Catalyst supports
Cerium
Cerium compounds
Crystal growth
Crystalline materials
Hydrogen
Monolayers
Temperature
Calcination
Acceso en línea:http://hdl.handle.net/20.500.12110/paper_03603199_v36_n24_p15899_Poggio
Aporte de:
Biblioteca Digital - Facultad de Ciencias Exactas y Naturales (UBA) de Universidad de Buenos Aires
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spelling todo:paper_03603199_v36_n24_p15899_Poggio2023-10-03T15:26:25Z Influence of the calcination temperature on the structure and reducibility of nanoceria obtained from crystalline Ce(OH)CO3 precursor Poggio, E. Jobbágy, M. Moreno, M. Laborde, M. Mariño, F. Baronetti, G. Catalysts COPROX Hydrogen purification Supports Calcination temperature Cell contraction CO-PROX Differential reactors Green method High yield Hydrogen purification Low temperatures Nano-ceria Nanotextured Optimum activity Preparation method Surface process Temperature range Calcination temperature CO-PROX Co-prox reactions Differential reactors Hydrogen purification Low temperatures Preparation method Temperature range Catalyst activity Catalyst supports Catalysts Cerium Cerium compounds Crystal growth Crystalline materials Hydrogen Monolayers Catalyst activity Catalyst supports Catalysts Crystalline materials Temperature Calcination Calcination A high yield green method was developed for the preparation of reactive nanotextured ceria (CeO2). The preparation method is based on the oxidation of a crystalline Ce(OH)CO3 precursor that decompose at relative low temperature (ca. 250 °C) yielding CeO2 nanocrystals initially rich in Ce3+. After increasing calcination temperatures (in the range 350-650 °C), PXRD analysis show a slight crystal growth after calcination temperatures up to 550 °C, however cell contraction in such case denotes the definitive oxidation of remnant Ce3+ centers. XPS results confirm Ce3+ fraction diminution as calcination temperature increases. TPR profiles of ceria samples show two reduction events being the low temperature one (at ca. 500 °C) related to a surface process in which approximately only one cerium monolayer is involved. Catalytic activity tests for COPROX reaction were performed under differential reactor conditions to evaluate their activity in the temperature range 100-300 °C. The optimum activity recorded for the sample calcined at 450 °C accounts for the compromise between oxide's activation and surface preservation. © 2011, Hydrogen Energy Publications, LLC. Published by Elsevier Ltd. All rights reserved. Fil:Jobbágy, M. Universidad de Buenos Aires. Facultad de Ciencias Exactas y Naturales; Argentina. JOUR info:eu-repo/semantics/openAccess http://creativecommons.org/licenses/by/2.5/ar http://hdl.handle.net/20.500.12110/paper_03603199_v36_n24_p15899_Poggio
institution Universidad de Buenos Aires
institution_str I-28
repository_str R-134
collection Biblioteca Digital - Facultad de Ciencias Exactas y Naturales (UBA)
topic Catalysts
COPROX
Hydrogen purification
Supports
Calcination temperature
Cell contraction
CO-PROX
Differential reactors
Green method
High yield
Hydrogen purification
Low temperatures
Nano-ceria
Nanotextured
Optimum activity
Preparation method
Surface process
Temperature range
Calcination temperature
CO-PROX
Co-prox reactions
Differential reactors
Hydrogen purification
Low temperatures
Preparation method
Temperature range
Catalyst activity
Catalyst supports
Catalysts
Cerium
Cerium compounds
Crystal growth
Crystalline materials
Hydrogen
Monolayers
Catalyst activity
Catalyst supports
Catalysts
Crystalline materials
Temperature
Calcination
Calcination
spellingShingle Catalysts
COPROX
Hydrogen purification
Supports
Calcination temperature
Cell contraction
CO-PROX
Differential reactors
Green method
High yield
Hydrogen purification
Low temperatures
Nano-ceria
Nanotextured
Optimum activity
Preparation method
Surface process
Temperature range
Calcination temperature
CO-PROX
Co-prox reactions
Differential reactors
Hydrogen purification
Low temperatures
Preparation method
Temperature range
Catalyst activity
Catalyst supports
Catalysts
Cerium
Cerium compounds
Crystal growth
Crystalline materials
Hydrogen
Monolayers
Catalyst activity
Catalyst supports
Catalysts
Crystalline materials
Temperature
Calcination
Calcination
Poggio, E.
Jobbágy, M.
Moreno, M.
Laborde, M.
Mariño, F.
Baronetti, G.
Influence of the calcination temperature on the structure and reducibility of nanoceria obtained from crystalline Ce(OH)CO3 precursor
topic_facet Catalysts
COPROX
Hydrogen purification
Supports
Calcination temperature
Cell contraction
CO-PROX
Differential reactors
Green method
High yield
Hydrogen purification
Low temperatures
Nano-ceria
Nanotextured
Optimum activity
Preparation method
Surface process
Temperature range
Calcination temperature
CO-PROX
Co-prox reactions
Differential reactors
Hydrogen purification
Low temperatures
Preparation method
Temperature range
Catalyst activity
Catalyst supports
Catalysts
Cerium
Cerium compounds
Crystal growth
Crystalline materials
Hydrogen
Monolayers
Catalyst activity
Catalyst supports
Catalysts
Crystalline materials
Temperature
Calcination
Calcination
description A high yield green method was developed for the preparation of reactive nanotextured ceria (CeO2). The preparation method is based on the oxidation of a crystalline Ce(OH)CO3 precursor that decompose at relative low temperature (ca. 250 °C) yielding CeO2 nanocrystals initially rich in Ce3+. After increasing calcination temperatures (in the range 350-650 °C), PXRD analysis show a slight crystal growth after calcination temperatures up to 550 °C, however cell contraction in such case denotes the definitive oxidation of remnant Ce3+ centers. XPS results confirm Ce3+ fraction diminution as calcination temperature increases. TPR profiles of ceria samples show two reduction events being the low temperature one (at ca. 500 °C) related to a surface process in which approximately only one cerium monolayer is involved. Catalytic activity tests for COPROX reaction were performed under differential reactor conditions to evaluate their activity in the temperature range 100-300 °C. The optimum activity recorded for the sample calcined at 450 °C accounts for the compromise between oxide's activation and surface preservation. © 2011, Hydrogen Energy Publications, LLC. Published by Elsevier Ltd. All rights reserved.
format JOUR
author Poggio, E.
Jobbágy, M.
Moreno, M.
Laborde, M.
Mariño, F.
Baronetti, G.
author_facet Poggio, E.
Jobbágy, M.
Moreno, M.
Laborde, M.
Mariño, F.
Baronetti, G.
author_sort Poggio, E.
title Influence of the calcination temperature on the structure and reducibility of nanoceria obtained from crystalline Ce(OH)CO3 precursor
title_short Influence of the calcination temperature on the structure and reducibility of nanoceria obtained from crystalline Ce(OH)CO3 precursor
title_full Influence of the calcination temperature on the structure and reducibility of nanoceria obtained from crystalline Ce(OH)CO3 precursor
title_fullStr Influence of the calcination temperature on the structure and reducibility of nanoceria obtained from crystalline Ce(OH)CO3 precursor
title_full_unstemmed Influence of the calcination temperature on the structure and reducibility of nanoceria obtained from crystalline Ce(OH)CO3 precursor
title_sort influence of the calcination temperature on the structure and reducibility of nanoceria obtained from crystalline ce(oh)co3 precursor
url http://hdl.handle.net/20.500.12110/paper_03603199_v36_n24_p15899_Poggio
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AT morenom influenceofthecalcinationtemperatureonthestructureandreducibilityofnanoceriaobtainedfromcrystallineceohco3precursor
AT labordem influenceofthecalcinationtemperatureonthestructureandreducibilityofnanoceriaobtainedfromcrystallineceohco3precursor
AT marinof influenceofthecalcinationtemperatureonthestructureandreducibilityofnanoceriaobtainedfromcrystallineceohco3precursor
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