Catalysis Today, Vol.223, 35-43, 2014
Continuous catalytic hydrothermal gasification of algal biomass and case study on toxicity of aluminum as a step toward effluents recycling
A novel process named SunCHem has been proposed to produce methane via catalytic hydrothermal gasification of microalgae [1-3]. The process is innovative because it is designed as a closed-cycle system with respect to water, nutrients and some of the CO2, which are recycled and reused for the growth of microalgae. However, this recycled hydrothermal input is a matter of concern because upon continuous operation, it may become enriched in potential toxicants for algae. This study concerns the investigation of (1) the continuous catalytic hydrothermal gasification of the microalgae Phaeodactylum tricornutum, and (2) the influence of aluminum on microalgae growth, as traces of this metal are expected in the hydrothermal effluent. Experiments with the algae P. tricornutum, demonstrated the technical feasibility of pumping algae slurry (6.5 wt.%) through the continuous pilot plant with simultaneous gasification for several hours. The carbon gasification efficiency, C-Gas/C-Feed, was ca. 31% at steady state. The catalyst was rapidly deactivated during the continuous gasification experiment, due to sulfur poisoning and coking. Concerning the study on the effect of soluble Al on freshwater microalgae, it was demonstrated that at alkaline conditions, the Al hydroxides had a negative effect on algae growth even at concentrations as low as 0.025 mg L-1. (C) 2013 Elsevier B.V. All rights reserved.
Keywords:Supercritical water gasification;Catalytic hydrothermal process;Microalgal biomass;Nutrient recovery;Aluminum toxicity;Methane