Transitioning an Alkaliphilic and Photosynthetic Microbial Consortium from Laboratory to Outdoor Demonstration Scale

Date
2023-10-05
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Abstract
The 21st century’s challenges—climate change, growing population, resource decline, habitat and species loss—mean that current practices must be replaced, redesigned, and improved. Phytoplankton, reliant on water, light, nutrients, and CO2, offer versatile applications in nutritional supplements, agricultural feed, bioplastics, wastewater treatment, and bioenergy production. Currently, the most successful commercial ventures center on select taxa like Spirulina and Chlorella and produce high-value products for human consumption. Expanding the scope of viable commercial taxa and their applications hinges on overcoming critical challenges in cultivation, notably biomass productivity, robustness, and resource use. Inspiration can be drawn from natural environments where phytoplankton flourish, like alkaline soda lakes. These lakes are characterized by elevated pH and high carbonate alkalinity. Growing phytoplankton in high pH (10+), high carbonate alkalinity medium (0.5 M) increases the driving force for CO2 capture into solution and helps exclude competitors and predators which can cause biomass instability. This thesis chronicles the transition of biomass from alkaline soda lakes, dominated by the cyanobacterium Sodalinema alkaliphilum, from laboratory to large-scale outdoor demonstration. Chapter 2 explores the microbes inhabiting such lakes and their societal applications. Chapter 3 describes the design, construction, and operation of laboratory photobioreactors with programmable lighting and online growth measurements. Chapter 4 follows outdoor biomass cultivation in a 1,000 L photobioreactor, demonstrating sustained growth at a pH sufficient for CO2 capture from air. In Chapter 5, cultivation in a 3,000 L open raceway pond (ORP) reports long-term medium re-use, water requirements, and CO2 capture from air, although optimisation is necessary. Operational seasons ranged 70–140 days—160 being the maximum possible in Calgary’s temperate climate. Average daily yields were ∼ 3–4 g/m2/day (ash-free) with modeling predicting productivity could reach 6 g/m2/day by reducing biomass density. Finally, Chapter 6 quantifies ORP biomass losses, with stable isotope probing unveiling insights into S. alkaliphilum physiology and ecology. In conclusion, this research explores the feasibility of growing S. alkaliphilum biomass at scale for extended durations and has generated baseline data and operational insights which can be used to inform and refine the sustainability and productivity of future iterations of this technology.
Description
Keywords
Sodalinema, Cyanobacteria, Alkaline soda lake, Biotechnology, Photobioreactor, Open raceway pond, Microalgae, Microbial consortium, Microbial community
Citation
Haines, M. V. (2023). Transitioning an alkaliphilic and photosynthetic microbial consortium from laboratory to outdoor demonstration scale (Doctoral thesis, University of Calgary, Calgary, Canada). Retrieved from https://prism.ucalgary.ca.