1. Energy-efficient outdoor cultivation of oleaginous microalgae at northern latitudes using waste heat and flue gas from a pulp and paper mill
- Author
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Susanne Ekendahl, Niklas Strömberg, Domitille Niyitegeka, Mathias Bark, Johan Engelbrektsson, and Carl-Anton Karlsson
- Subjects
Flue gas ,business.industry ,020209 energy ,Paper mill ,02 engineering and technology ,010501 environmental sciences ,Photosynthetic efficiency ,Carbon sequestration ,Pulp and paper industry ,01 natural sciences ,Dewatering ,Energy storage ,Waste heat ,0202 electrical engineering, electronic engineering, information engineering ,Environmental science ,business ,Agronomy and Crop Science ,0105 earth and related environmental sciences ,Efficient energy use - Abstract
Energy efficient cultivation is the major bottleneck for microalgal biomass production on a large scale and considered very difficult to attain at northern latitudes. In this study an unconventional method for industrial microalgae cultivation for bio-oil production using pulp and paper mill waste resources while harvesting only once a year was performed, mainly in order to investigate the energy efficiency of the process. Algae were cultivated for three months in 2014 in covered pond systems with access to flue gas and waste heat from the industry, and the biomass was recovered as thick sediment sludge after dewatering. The cultivation systems, designed to manage the waste resources, reached a promising photosynthetic efficiency of at most 1.1%, a net energy ratio (NER) of 0.25, and a projected year-round energy biomass yield per area 5.2 times higher than corresponding rapeseed production at the location. Thus, microalgae cultivation was, for the first time, proven energy efficient in a cold continental climate. Energy-rich indigenous communities quickly out-competed the oleaginous monocultures used for inoculation. The recovered biomass had higher heating values of 20–23 MJ kg− 1 and contained 14–19% oil dominated by C16 followed by C18 fatty acids. The cultivation season at 59°15′N, 14°18′E was projected to be efficient for 10 months and waste heat drying of the biomass is suggested for two winter months. The technique is proposed for carbon sequestering and energy storage in the form of microalgal sludge or dry matter for later conversion into biochemicals.
- Published
- 2018