ABSTRACT
In this study, we developed a method for simultaneous bio-methanation of CO2 and CO with H2 in a single bioreactor using a combination of carboxydotrophic bacteria and methanogenic archaea for industrial applications. Methanogenic archaea generally use H2 and CO2 to produce methane, whereas very few methanogenic archaea methanize CO, and these grow slowly and consequently produce low reactant gas turnover rates. Thus, to achieve fast and simultaneous transformation of CO and CO2, we identified a combination of carboxydotrophic and hydrogenogenic bacteria and methanogenic archaea that can produce H2 and CO2 from CO, and then methanize CO2 and H2. The present screening experiments identified carboxydotrophic bacteria and methanogenic archaea that can cohabitate at the same thermophilic temperature and pH ranges and in the same growth medium. In these experiments, combinations of Carboxydocella thermautotrophica (DSM 12326), Carboxydocella sporoproducens (DSM 16521), and three thermophilic rod-shaped methanogenic archaeal cultures from MicroPyros GmbH formed unique microbial co-cultures that transformed CO2, H2, and CO to methane. The successful combination of these microbes could be used to gasify biowastes, such as sewage sludge, as alternative sources of hydrogen for microbial power-to-gas processes. Accordingly, gasification under these conditions produced H2-rich gas containing CO2 and CO, theoretically allowing various types of biowastes to be converted to biomethane, which is CO2-neutral, storable, and widely applicable as an energy source.