Promising Pathway for Algal Biofuels through Wastewater Cultivation and Hydrothermal Conversion

Promising Pathway for Algal Biofuels through Wastewater Cultivation and Hydrothermal Conversion

The purpose of this study is to demonstrate feasibility of an integrated wastewater algae-to-biocrude process that can sustainably cultivate algal biomass for biofuel production. This process used pilot-scale algal cultivation ponds fed with municipal wastewater as the nutrient source. The open pond...

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Bibliographic Details
Published in:Energy & fuels Vol. 27; no. 2; pp. 857 - 867
Main Authors: Roberts, Griffin W, Fortier, Marie-Odile P, Sturm, Belinda S. M, Stagg-Williams, Susan M
Format: Journal Article
Language:English
Published: American Chemical Society 21-02-2013
Subjects:
Algae
Biomass
Carbon
Cultivation
Drying
Fuels
Liquefaction
Ponds
Waste water
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Summary:The purpose of this study is to demonstrate feasibility of an integrated wastewater algae-to-biocrude process that can sustainably cultivate algal biomass for biofuel production. This process used pilot-scale algal cultivation ponds fed with municipal wastewater as the nutrient source. The open ponds were self-inoculated from the wastewater source, resulting in a mixed-culture microalgal community with distinct differences compared to laboratory-maintained and fertilized monocultures: 29.0% dry weight (dw) ash, 48.9% ash-free dry weight (afdw) carbon, 37.5% afdw oxygen, and 14.0% afdw lipid. The harvested algae was processed using hydrothermal liquefaction at 350 °C (autogenous pressures up to 2000 psig) for 1 h using 3 g of freeze-dried algae and 50 mL of water. The yield of biocrude was 44.5 ± 4.7% afdw, with an elemental weight percent composition of 78.7% carbon, 10.1% hydrogen, 4.4% nitrogen, and 5.5% oxygen and an energy content of 39 MJ/kg. Hydrothermal processing also resulted in the formation of 18.4 ± 4.6% afdw aqueous co-products (ACPs) and 45.0 ± 5.9% dw solid biochar. The ACPs contained 4550 ± 460 mg L–1 organic carbon, 1640 ± 250 mg L–1 total nitrogen, and 3.5 mg L–1 total phosphorus. The solid biochar product contained >20% dw carbon with an energy density between 8 and 10 MJ kg–1. This study is the first hydrothermal liquefaction paper of wastewater-derived microalgae. The municipal wastewater matrix and resultant mixed-culture biomass significantly influenced liquefaction product distribution, yielding a higher proportion of biochar, which may be a valuable co-product. This paper explores the potential for wastewater-fed algal systems integrated with hydrothermal liquefaction, which together overcome challenges identified by the 2012 National Research Council’s report on algal biofuel sustainability.
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ISSN:0887-0624
1520-5029
DOI:10.1021/ef3020603