Feasibility of closing nutrient cycles from black water by microalgae-based technology

Feasibility of closing nutrient cycles from black water by microalgae-based technology

•Microalgae efficiently remove nutrients from wastewater under Dutch natural light.•Chlorella sorokiniana and Chlorococcum sp. sustain growth at nitrite ≥ 1 g.L−l.•Based on nutrient composition microalgal biomass can be used as organic fertilizer. Microalgae can recover macronutrients and trace elem...

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Bibliographic Details
Published in:Algal research (Amsterdam) Vol. 44; p. 101715
Main Authors: Silva, Gustavo H.R., Sueitt, Ana Paula E., Haimes, Sarah, Tripidaki, Aikaterini, van Zwieten, Ralph, Fernandes, Tânia V.
Format: Journal Article
Language:English
Published: Elsevier B.V 01-12-2019
Subjects:
Anaerobically-digested black water
Nitrifying bacteria
Nitrogen recovery
Organic fertilizer
Phosphorus recovery
Nitrifying bacteria
Organic fertilizer
Phosphorus recovery
Anaerobically-digested black water
Nitrogen recovery
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Summary:•Microalgae efficiently remove nutrients from wastewater under Dutch natural light.•Chlorella sorokiniana and Chlorococcum sp. sustain growth at nitrite ≥ 1 g.L−l.•Based on nutrient composition microalgal biomass can be used as organic fertilizer. Microalgae can recover macronutrients and trace elements from wastewaters. The microalgae biomass can then be used as fertilizer to enrich impoverished agricultural soils by increasing the soil´s carbon content and providing essential nutrients for soil health. Using microalgae for wastewater treatment will enable the shift from linear sanitation systems to circular ones where the carbon and nutrient cycles can be closed. By using a nutrient-rich wastewater medium for microalgae cultivation, high biomass productivity and, therefore, high nutrient recovery, can be achieved. In this study, we demonstrated that Chlorella sorokiniana and Chlorococcum sp. were able to grow in and remove nitrogen and phosphorus from anaerobically-digested black water (AnBW), in a 211 L tubular photobioreactor (PBR), placed in a temperature-controlled (25 °C) glass greenhouse, under Dutch natural light conditions (5.8 to 23.3 mol photons.m−2.d-1 and 67 to 270 μmol.s-1. m−2). The microalgae productivity varied from 0.13 g DW.L-1.d-1 (autumn) to 0.36 g DW.L-1.d-1 (summer). The nitrogen and phosphorus removal rates were 28 to 62 mg.L-l.d-1 and 2.3 to 5.4 mg.L-l.d-1, respectively. Due to the insufficient light availability for the high nitrogen and phosphorus concentrations of the AnBW cultivation medium (1280 mg.L-l and 68 mg.L-l, respectively), the overall nutrient removal efficiencies remained below 50% even during the summer period when light intensity was at its highest. Partial nitrification was confirmed by the accumulation of nitrite (≥ 1000 mg NO2-N.L-l) in the PBR. These high NO2 concentrations did not, however, hinder microalgae growth. The macronutrient and trace element compositions of the dry microalgal biomass were similar to commercially available organic fertilizers, indicating a potential for soil enrichment.
ISSN:2211-9264
2211-9264
DOI:10.1016/j.algal.2019.101715