Hydrogen production of nickel–scandia-stabilized zirconia and copper/nickel–scandia-stabilized zirconia catalysts through steam methane reforming for solid oxide fuel cell operation

Hydrogen production of nickel–scandia-stabilized zirconia and copper/nickel–scandia-stabilized zirconia catalysts through steam methane reforming for solid oxide fuel cell operation

In this study, the catalytic activities of the steam methane reforming (SMR) reactions with two catalysts, including nickel–scandia-stabilized zirconia (Ni–SSZ) and copper/nickel–scandia-stabilized zirconia ( Cu/Ni–SSZ), were examined and compared. The microstructure and crystallinity of the as-prep...

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Bibliographic Details
Published in:Clean technologies and environmental policy Vol. 20; no. 9; pp. 2067 - 2074
Main Authors: Uma, Kasimayan, Chu, Chia-Hui, Pan, Guan-Ting, Yang, Thomas C.-K., Wang, Sea-Fue
Format: Journal Article
Language:English
Published: Berlin/Heidelberg Springer Berlin Heidelberg 01-11-2018
Springer Nature B.V
Subjects:
Annealing
Carbon
Carbon dioxide
Catalysis
Catalysts
Conversion
Copper
Crystal defects
Crystallites
Crystals
Earth and Environmental Science
Environment
Environmental Economics
Environmental Engineering/Biotechnology
Environmental policy
Experiments
Hydrogen
Hydrogen production
Immunoglobulins
Industrial and Production Engineering
Industrial Chemistry/Chemical Engineering
Mass spectroscopy
Methane
Nickel
Nuclear fuels
Original Paper
Raman spectroscopy
Reaction kinetics
Reducing atmospheres
Reforming
Scandium oxides
Scanning electron microscopy
Selectivity
Solid oxide fuel cells
Sustainable Development
Thermogravimetric analysis
Time dependence
Verification
X-ray diffraction
Zirconia
Zirconium dioxide
generation
H
reforming
CH
Solid oxide fuel cell
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Summary:In this study, the catalytic activities of the steam methane reforming (SMR) reactions with two catalysts, including nickel–scandia-stabilized zirconia (Ni–SSZ) and copper/nickel–scandia-stabilized zirconia ( Cu/Ni–SSZ), were examined and compared. The microstructure and crystallinity of the as-prepared catalysts were characterized by scanning electron microscopy, Raman spectroscopy, and X-ray diffraction. Mass spectrometer was applied in the outlet streams, in order to simultaneously monitor the time-dependent kinetics in the reactor for an activity test and conversion examination. Finally, thermogravimetric analysis (TGA) and Raman spectrometer were implemented for further verification of carbon residuals on the catalysts. It was found that the incorporation of Cu on Ni–SSZ imposed significant constraints on the growth of nickel crystallites from NiO during the annealing process in reducing atmospheres. The methane conversion of Ni–SSZ and Cu/Ni–SSZ catalysts (annealed at 300 °C for 2 h) was 36.2 and 26.0%, respectively. However, the amount of carbon residuals on Cu/Ni–SSZ catalyst (300 °C for 2 h) was 18.6%, which is lower than that of the Ni–SSZ catalysts (33.2%) from TGA results. Further Raman experiments revealed that more graphite-like carbon residuals and less defects or amorphous carbons ( I G / I D  = 2.0) were found in the case of Cu/Ni–SSZ catalysts (300 °C for 2 h). Among the catalysts in this study, the Cu/Ni–SSZ catalyst (300 °C for 2 h) is considered as a promising catalyst for SMR reaction, since it has a fair methane conversion, and characterized higher CO 2 selectivity and lower CO selectivity without compromising the hydrogen purity. More importantly, the least amount of carbon residuals was found in Cu/Ni–SSZ catalyst (300 °C for 2 h), which assured a better lifetime.
ISSN:1618-954X
1618-9558
DOI:10.1007/s10098-018-1591-6