Release rates and potential fates of nitrogen and phosphorus from sediments in a eutrophic reservoir

• Published in: Freshwater biology Vol. 50; no. 2; pp. 301 - 322
• Main Authors: NOWLIN, WESTON H., EVARTS, JENNIFER L., VANNI, MICHAEL J.
• Format: Journal Article
• Language: English
• Published: Oxford, UK Blackwell Science Ltd 01.02.2005; Blackwell Science; Wiley Subscription Services, Inc
• Subjects: Animal and plant ecology; Animal, plant and microbial ecology; Biological and medical sciences; Dorosoma cepedianum; Fresh water ecosystems; Freshwater; Fundamental and applied biological sciences. Psychology; gizzard shad; nutrient release; phosphorus; sediments; Synecology; thermal stratification; USA, Ohio, Acton L; Freshwater environment; nutrient release; Hydrobiology; thermal stratification; Artificial lake; Phosphorus; Reservoir; Nitrogen; Sediments; gizzard shad; Eutrophication
• ISSN: 0046-5070; 1365-2427
• DOI: 10.1111/j.1365-2427.2004.01316.x

Summary 1. Nutrients released from lake sediments can influence water column nutrient concentrations and planktonic productivity. We examined sediment nutrient release [soluble reactive phosphorus (SRP) and ammonia (NH)] at two sites in a eutrophic reservoir (Acton Lake, OH, U.S.A.) that differed in physical mixing conditions (a thermally stratified and an unstratified site). 2. Sediment nutrient release rates were estimated with three methods: sediment core incubations, seasonal in situ hypolimnetic accumulation and a published regression model that predicted sediment phosphorous (P) release rate from sediment P concentration. All three methods were applied to the deeper stratified site in the reservoir; however, we used only sediment core incubations to estimate SRP and NH release rates at the shallow unstratified site because of the lack of thermal stratification. We also compared the total P concentration (TPS) of sediments and the concentration of P in various sediment fractions at both sites. 3. Anoxic sediments at the stratified site released SRP at rates more than an order of magnitude greater than oxic sediments at the shallow unstratified site. However, P accumulated in the hypolimnion at much lower rates than predicted by sediment core incubations. In contrast, NH was released at similar rates at both sites and accumulated in the hypolimnion at close to the expected rate, indicating that P was ‘lost’ from the hypolimnion through biogeochemical pathways for P, such as precipitation with inorganic material or biological uptake and sedimentation. 4. TPS was significantly greater at the deeper stratified site and organically bound P accounted for >50% of TPS at both sites. 5. We examined the magnitude of SRP fluxes into the study reservoir in 1996 by comparing the mean summer daily SRP fluxes from anaerobic sediments, aerobic sediments, stream inflows and gizzard shad excretion. While the SRP release from anaerobic sediments was high, we hypothesise that little of this SRP gained access to the epilimnion in mid‐summer. SRP flux to the reservoir from aerobic sediments was less than from gizzard shad excretion and streams. Large interannual variability in thermocline stability, gizzard shad biomass and stream discharge volumes, will affect SRP loading rates from different sources in different years. Therefore, construction of P budgets for different years should account for interannual variation in these parameters.