Synergistic Effects of Inexpensive Mixed Metal Oxides for Catalytic Hydrothermal Liquefaction of Food Wastes

Industrial wastes and natural mixed oxide materials were evaluated as inexpensive heterogeneous catalysts for catalytic hydrothermal liquefaction (CHTL) of food wastes. Red mud and red clay achieved biocrude carbon yields of 47.0 and 39.5% with higher heating values (HHVs) of 40.2 and 37.7 MJ kg–1,...

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Bibliographic Details
Published in:ACS sustainable chemistry & engineering 2020-05, Vol.8 (17), p.6877-6886
Main Authors: Cheng, Feng, Tompsett, Geoffrey A, Murphy, Caroline M, Maag, Alex R, Carabillo, Nicholas, Bailey, Marianna, Hemingway, Jeremy J, Romo, Carla I, Paulsen, Alex D, Yelvington, Paul E, Timko, Michael T
Format: Article
Language:English
Subjects:
biocrude oil
biofuels
catalytic
clay
food waste
heterogeneous catalysts
hydrothermal liquefaction
INORGANIC, ORGANIC, PHYSICAL, AND ANALYTICAL CHEMISTRY
oxides
red clay
red mud
wastes
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Summary:Industrial wastes and natural mixed oxide materials were evaluated as inexpensive heterogeneous catalysts for catalytic hydrothermal liquefaction (CHTL) of food wastes. Red mud and red clay achieved biocrude carbon yields of 47.0 and 39.5% with higher heating values (HHVs) of 40.2 and 37.7 MJ kg–1, respectively, which were much greater than those without the catalyst (biocrude carbon yield of 19.7% and HHV of 36.1 MJ kg–1). Biocrude characterization revealed that similar families of molecules were formed in the presence and absence of catalysts, implying that the main role of the catalyst is to promote rates of thermal reactions, leading to biocrude production without opening new pathways. The crystalline structures of inexpensive mixed oxides were stable under hydrothermal conditions, with modest calcium leaching (7.5%) and trace leaching of other metals. Using red clay or red mud resulted in >40% recovery of the energy in food waste as biocrude, greater than that obtained under noncatalytic conditions (18%) or from any individual constituent oxide (19–27%). The improved CHTL performance of the mixed metal oxides compared with single-metal oxides was attributed to the synergistic effects of base and acid sites present on catalyst surfaces; mixed oxides presented balanced densities of acids and bases, whereas the constituent oxides were either primarily acidic or primarily basic. The percent of energy recovered as biocrude oil was strongly correlated with the base-to-acid site density ratio, providing an important performance predictor for CHTL conversion of food waste to bioenergy.
ISSN:2168-0485
2168-0485
DOI:10.1021/acssuschemeng.0c02059