Internal iron loading and warm temperatures are preconditions for cyanobacterial dominance in embayments along Georgian Bay, Great Lakes

• Published in: Canadian journal of fisheries and aquatic sciences Vol. 74; no. 9; pp. 1439 - 1453
• Main Authors: Verschoor, Mark J, Powe, Chistopher R, McQuay, Eric, Schiff, Sherry L, Venkiteswaran, Jason J, Li, Jiahua, Molot, Lewis A
• Format: Journal Article
• Language: English
• Published: Ottawa NRC Research Press 01.09.2017; Canadian Science Publishing NRC Research Press
• Subjects: Algae; Ammonium; Anoxia; Aquatic environment; Aquatic sciences; Bays; Biomass; Cyanobacteria; Cyanophyceae; Dominance; Environmental aspects; Eutrophic environments; Eutrophic lakes; Eutrophic waters; Eutrophication; Freshwater; Iron; Lakes; Phosphorus; Phytoplankton; Sediments; Studies; Summer; Temperature; Canada; Lake Huron; Georgian Bay; Canada, Ontario, Lake Huron, Georgian Bay
• ISSN: 0706-652X; 1205-7533
• DOI: 10.1139/cjfas-2016-0377

Previous work suggests that a high rate of internal ferrous iron (Fe 2+ ) loading from anoxic sediments into overlying waters favours cyanobacteria dominance (>50% of the phytoplankton biomass) over eukaryotic algae. This Cyanobacteria–Ferrous conceptual model was assessed along the Georgian Bay coastline of Lake Huron, Ontario, in one meso-eutrophic and three oligotrophic embayments that experience natural hypolimnetic anoxia. Cyanobacteria dominated all embayments in the relatively warmer summer of 2012 but not in the much cooler summer of 2014, although hypolimnetic anoxia and internal Fe 2+ loading were observed in both summers in all embayments. A cyanobacteria bloom large enough to turn the lake visibly green was observed only in warmer 2012 in the meso-eutrophic embayment. Results show that warm summer temperatures and internal Fe 2+ loading are necessary preconditions for cyanobacteria dominance, while high nutrient levels are needed to form large blooms. There were no consistent patterns between dominance and total and dissolved phosphorus (P), total nitrogen, ammonium, and nitrate. Internal P loading was not a necessary precondition for dominance. While P removal programs will decrease phytoplankton biomass in eutrophic waters, oxidized surficial sediments must be maintained throughout an aquatic system to prevent cyanobacteria dominance.