Using Simulated Flue Gas to Rapidly Grow Nutritious Microalgae with Enhanced Settleability.

Favorable microalgal nutrition from waste resources and improved harvesting methods would offset costs for a process that could be scaled up to treat pollution and produce valuable animal feed in lieu of soy protein. Co-benefits include avoidance of carbon dioxide emissions, which may provide an additional revenue stream when carbon markets begin to flourish. To sustainably achieve these goals at scale, barriers to microalgal production such as tolerance for waste streams and dramatic improvement in dewatering and settleability of the microalgae must be overcome. Presently, it is largely assumed that nutritious microalgae, including , would be inhibited by SO and NO in flue gases and settle slowly as discrete particles. Studies conducted with a 2 L photobioreactor, sparged with simulated coal-fired power plant flue gas, demonstrated that both biomass productivity and settling rates were increased. The average maximum biomass productivity was 700 ± 40 mg L d, which significantly exceeded that of the control culture (510 ± 40 mg L d). Thirty-minute trials of modeled bulk settling showed rapid coagulation, likely facilitated by extracellular polymeric substances, and compaction when the cultures were grown with simulated emissions. Control cultures, not exposed to the additional toxicants in flue gas, settled as discrete particles and did not show any settling progress within 30 min. Of the SO sparged into the cultivation system, (111 ± 4)% was captured as either SO in the medium or fixed in the biomass. The stress of simulated-emissions exposure decreased the protein contents and altered the amino acid profiles but did not decrease the fraction of methionine, a valuable amino acid in animal feed.