Oxygen consumption in seasonally stratified lakes decreases only below a marginal phosphorus threshold

Müller, Beat; Steinsberger, Thomas; Schwefel, Robert; Gächter, René; Sturm, Michael; Wüest, Alfred

doi:10.1038/s41598-019-54486-3

Cited by 28 publications

(37 citation statements)

References 35 publications

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“…Below a TP concentration of ~ 10 mg P m −3 , WCM covaries closely with TP concentration. This is in line with the observation of Müller et al (2019) that AHM in seasonally stratified lakes increases approximately in proportion to the areal amount of bio‐available P but levels off above this threshold value. O 2 consumption in lakes > 100 m deep may immediately respond to a decrease of TP for concentrations below this threshold.…”

Section: Discussionsupporting

confidence: 93%

Hypolimnetic oxygen depletion rates in deep lakes: Effects of trophic state and organic matter accumulation

Steinsberger

Schwefel

Wüest

et al. 2020

Limnology & Oceanography

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This study investigated the consumption of oxygen (O 2) in 11 European lakes ranging from 48 m to 372 m deep. In lakes less than~100 m deep, the main pathways for O 2 consumption were organic matter (OM) mineralization at the sediment surface and oxidation of reduced compounds diffusing up from the sediment. In deeper lakes, mineralization of OM transported through the water column to the sediment represented a greater proportion of O 2 consumption. This process predominated in the most productive lakes but declined with decreasing total phosphorous (TP) concentrations and hence primary production, when TP concentrations fell below a threshold value of~10 mg P m −3. Oxygen uptake by the sediment and the flux of reduced compounds from the sediment in these deep lakes were 7.9-10.6 and 0.6-3.6 mmol m −2 d −1 , respectively. These parameters did not depend on the lake's trophic state but did depend on sedimentation rates for the primarily allochthonous or already degraded OM. These results indicate that in lakes deeper than~100 m, mineralization of autochthonous OM is mostly complete by the time of sedimentary burial. This explains why hypolimnetic O 2 concentrations improve more rapidly following TP load reduction in deeper lakes relative to shallower lakes, where larger sediment-based O 2 consumption by settled OM and release of reduced substances may inhibit the restoration of hypolimnetic O 2 concentrations.

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Section: Discussionsupporting

confidence: 93%

Hypolimnetic oxygen depletion rates in deep lakes: Effects of trophic state and organic matter accumulation

Steinsberger

Schwefel

Wüest

et al. 2020

Limnology & Oceanography

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“…Phytoplankton is dominated by the cyanobacterium Planktothrix rubescens . Over the past few decades, the lake has undergone a remediation phase, which has curtailed water column total P concentrations from 520 mg P m −3 in the 1970s to ~ 24 mg P m −3 today (Müller et al 2019 ). Moreover, peak N was observed in the 1980s with up to 2.3 g N m −3 (Wehrli et al 1997 ).…”

Section: Methodsmentioning

confidence: 99%

“…This can be excluded in Lake Baldegg with its high concentration of NO 3 − that was never exhausted in the productive zone, because the lake was fully productive since more than a century (Lotter 1998) with P concentration not limiting production. Indicative for the situation is the hypolimnetic O 2 consumption that is unchanged since measurements begun in 1983 even though TP concentration decreased from 520 to 25 mg m −3 (Müller et al 2019), and net ecosystem production of ~ 90 g C m −2 year −1 both in 1995/1996 (Müller et al 2012) and 2013(Steinsberger et al 2017 determined from sediment traps. Hence, the good correlation between NRR and load requires that a large fraction of the imported N is removed within the epilimnion, e.g.…”

Section: Load-dependent Nitrogen Removal Rate In Lake Baldeggmentioning

confidence: 99%

Nitrogen removal processes in lakes of different trophic states from on-site measurements and historic data

et al. 2021

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Freshwater lakes are essential hotspots for the removal of excessive anthropogenic nitrogen (N) loads transported from the land to coastal oceans. The biogeochemical processes responsible for N removal, the corresponding transformation rates and overall removal efficiencies differ between lakes, however, it is unclear what the main controlling factors are. Here, we investigated the factors that moderate the rates of N removal under contrasting trophic states in two lakes located in central Switzerland. In the eutrophic Lake Baldegg and the oligotrophic Lake Sarnen, we specifically examined seasonal sediment porewater chemistry, organic matter sedimentation rates, as well as 33-year of historic water column data. We find that the eutrophic Lake Baldegg, which contributed to the removal of 20 ± 6.6 gN m−2 year−1, effectively removed two-thirds of the total areal N load. In stark contrast, the more oligotrophic Lake Sarnen contributed to 3.2 ± 4.2 gN m−2 year−1, and had removed only one-third of the areal N load. The historic dataset of the eutrophic lake revealed a close linkage between annual loads of dissolved N (DN) and removal rates (NRR = 0.63 × DN load) and a significant correlation of the concentration of bottom water nitrate and removal rates. We further show that the seasonal increase in N removal rates of the eutrophic lake correlated significantly with seasonal oxygen fluxes measured across the water–sediment interface (R2 = 0.75). We suggest that increasing oxygen enhances sediment mineralization and stimulates nitrification, indirectly enhancing denitrification activity.

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“…The main processes that cause AHOD in lakes are (1) the mineralisation and respiration of PPR settling in the water column, (2) the further processing of PPR recently deposited at the sediment's surface and (3) the oxidation of reduced substances (e.g. ammonium, hydrogen sulphide and methane) released from the sediments (Müller et al, 2019). A strong coupling between PPR and AHOD should arise where/when processes (1) and (2) are predominant, whereas process (3) could weaken the PPR-AHOD link.…”

Section: Controls Of Hypolimnetic Domentioning

confidence: 99%

“…1) to investigate the effect of phosphorus reduction on hypolimnetic oxygen. We hypothesised that this effect was weak because (1) primary productivity is relatively unaffected by phosphorus at high-to-moderate concentrations (Anneville & Pelletier, 2000;Müller et al, 2019) and (2) the transmission of effects through the phosphorus-hypolimnetic oxygenation pathway is dampened by external variation (i.e. by variables external to trophic state; Rogora et al, 2018).…”

Section: Introductionmentioning

confidence: 99%

Effects of phosphorus control on primary productivity and deep-water oxygenation: insights from Lake Lugano (Switzerland and Italy)

Lepori

Capelli

2020

Hydrobiologia

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Attempts to restore Lake Lugano, Switzerland and Italy, from eutrophication have produced weak responses in the target variables (primary productivity and hypolimnetic oxygen concentrations), indicating shortcomings in the underlying eutrophication model. An analysis of monitoring data showed that the decrease in phosphorus concentration, although nearly compliant with restoration targets, produced only slight decreases in primary productivity and no change in hypolimnetic oxygen conditions. These target variables were equally or more sensitive to factors external to trophic state, including plankton structure, which influenced primary productivity, and the depth of mixing during turnovers, which influenced hypolimnetic oxygen. To improve the chance of success, the restoration approach should revise the phosphorus concentration target and explicitly account for the influence of external variation, especially mixing depth.

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Oxygen consumption in seasonally stratified lakes decreases only below a marginal phosphorus threshold

Cited by 28 publications

References 35 publications

Hypolimnetic oxygen depletion rates in deep lakes: Effects of trophic state and organic matter accumulation

Hypolimnetic oxygen depletion rates in deep lakes: Effects of trophic state and organic matter accumulation

Nitrogen removal processes in lakes of different trophic states from on-site measurements and historic data

Effects of phosphorus control on primary productivity and deep-water oxygenation: insights from Lake Lugano (Switzerland and Italy)

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