Nutrient removal in an algal membrane photobioreactor: effects of wastewater composition and light/dark cycle
Graesiella emersonii was cultivated in an osmotic membrane photobioreactor (OMPBR) for nutrients removal from synthetic wastewater in continuous mode. At 1.5 days of hydraulic retention time and under continuous illumination, the microalgae removed nitrogen (N) completely at influent NH 4 + -N conce...
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Veröffentlicht in: | Applied microbiology and biotechnology 2019-04, Vol.103 (8), p.3571-3580 |
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Format: | Artikel |
Sprache: | eng |
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Zusammenfassung: | Graesiella emersonii
was cultivated in an osmotic membrane photobioreactor (OMPBR) for nutrients removal from synthetic wastewater in continuous mode. At 1.5 days of hydraulic retention time and under continuous illumination, the microalgae removed nitrogen (N) completely at influent NH
4
+
-N concentrations of 4–16 mg/L, with removal rates of 3.03–12.1 mg/L-day. Phosphorus (P) removal in the OMPBR was through biological assimilation as well as membrane rejection, but PO
4
3−
-P assimilation by microalgae could be improved at higher NH
4
+
-N concentrations. Microalgae biomass composition was affected by N/P ratio in wastewater, and a higher N/P ratio resulted in higher P accumulation in the biomass. The OMPBR accumulated about 0.35 g/L biomass after 12 days of operation under continuous illumination. However, OMPBR operation under 12 h light/12 h dark cycle lowered biomass productivity by 60%, which resulted in 20% decrease in NH
4
+
-N removal and nearly threefold increase in PO
4
3−
-P accumulation in the OMPBR. Prolonged dark phase also affected carbohydrate accumulation in biomass, although its effects on lipid and protein accumulation were negligible. The microalgae also exhibited high tendency to aggregate and settle, which could be attributed to reduction in cell surface charge and enrichment of soluble algal products in the OMPBR. Due to a relatively shorter operating period, membrane biofouling and salt accumulation did not influence the permeate flux significantly. These results improve the understanding of the effects of N/P ratio and light/dark cycle on biomass accumulation and nutrients removal in the OMPBR. |
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ISSN: | 0175-7598 1432-0614 |
DOI: | 10.1007/s00253-019-09696-0 |