TY - JOUR
T1 - Origin and Nature of Coke in Ethanol Steam Reforming and Its Role in Deactivation of Ni/La2O3-αAl2O3 Catalyst
AU - Montero, Carolina
AU - Remiro, Aingeru
AU - Valle, Beatriz
AU - Oar-Arteta, Lide
AU - Bilbao, Javier
AU - Gayubo, Ana G.
PY - 2019
Y1 - 2019
N2 - Deactivation of Ni/La2O3-αAl2O3 catalyst in ethanol steam reforming (ESR) was studied in order to establish the optimal conditions for maximizing H2 production and achieving steady behavior. The ESR reactions were conducted in a fluidized bed reactor under the following operating conditions: 500-650 °C; space-time up to 0.35 gcatalyst h/gEtOH; and steam/ethanol (S/E) molar ratio in the feed, 3-9. The features of the deactivated catalysts and the nature and morphology of the coke deposited were analyzed by temperature-programmed oxidation, X-ray diffraction, scanning electron microscopy, and Raman spectroscopy. Catalyst deactivation was solely caused by coke deposition, especially by encapsulating coke, with acetaldehyde, ethylene, and ethanol being the main precursors, whose concentration was high for lower values of space-time. Conversely, the filamentous coke formed from CH4 and CO (with their highest concentration for intermediate values of space-time) had a much lower impact on deactivation. Owing to the effect of space-time on the extent of reactions leading to the formation of coke precursors, the Ni/La2O3-αAl2O3 catalyst stability was enhanced by increasing space-time. The increase in temperature and S/E ratio was also beneficial since both variables promoted coke gasification. Consequently, a steady H2 yield throughout 200 h reaction was attained at 600 °C, a space-time of 0.35 gcatalyst h/gEtOH, and S/E > 3.
AB - Deactivation of Ni/La2O3-αAl2O3 catalyst in ethanol steam reforming (ESR) was studied in order to establish the optimal conditions for maximizing H2 production and achieving steady behavior. The ESR reactions were conducted in a fluidized bed reactor under the following operating conditions: 500-650 °C; space-time up to 0.35 gcatalyst h/gEtOH; and steam/ethanol (S/E) molar ratio in the feed, 3-9. The features of the deactivated catalysts and the nature and morphology of the coke deposited were analyzed by temperature-programmed oxidation, X-ray diffraction, scanning electron microscopy, and Raman spectroscopy. Catalyst deactivation was solely caused by coke deposition, especially by encapsulating coke, with acetaldehyde, ethylene, and ethanol being the main precursors, whose concentration was high for lower values of space-time. Conversely, the filamentous coke formed from CH4 and CO (with their highest concentration for intermediate values of space-time) had a much lower impact on deactivation. Owing to the effect of space-time on the extent of reactions leading to the formation of coke precursors, the Ni/La2O3-αAl2O3 catalyst stability was enhanced by increasing space-time. The increase in temperature and S/E ratio was also beneficial since both variables promoted coke gasification. Consequently, a steady H2 yield throughout 200 h reaction was attained at 600 °C, a space-time of 0.35 gcatalyst h/gEtOH, and S/E > 3.
UR - http://www.scopus.com/inward/record.url?scp=85070692901&partnerID=8YFLogxK
U2 - 10.1021/acs.iecr.9b02880
DO - 10.1021/acs.iecr.9b02880
M3 - Article
AN - SCOPUS:85070692901
SN - 0888-5885
VL - 58
SP - 14736
EP - 14751
JO - Industrial and Engineering Chemistry Research
JF - Industrial and Engineering Chemistry Research
IS - 32
ER -