Extreme diel dissolved oxygen and carbon cycles in shallow vegetated lakes

Andersen, Mikkel René; Kragh, Theis; Sand‐Jensen, Kaj

doi:10.1098/rspb.2017.1427

Cited by 73 publications

(79 citation statements)

References 46 publications

(88 reference statements)

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“…of the water column) contrasts with findings of Vilas et al (2017), who found oxygen effects at 50% P. crispus cover in a shallow Australian lake following temperature stratification (not observed in the unstratified hydropeaking reservoir, but see also Andersen et al, 2017;Ribaudo et al, 2018;Torma & Wu, 2019). The main mechanisms involved in these small-scale differences likely involve and ferrous iron from bottom sediments (Andersen et al, 2017;James, Dechamps, Turyk, & McGinley, 2007;Ribaudo et al, 2018).…”

Section: Spatial Scales Of Invasive Macrophyte Effectsmentioning

confidence: 65%

Invasive macrophytes induce context‐specific effects on oxygen, pH, and temperature in a hydropeaking reservoir

Moore

Clearwater²,

Duggan

et al. 2020

River Research & Apps

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Dense macrophyte beds are known to produce extreme diurnal oxygen and temperature conditions in shallow lakes. However their influences in managed hydropeaking reservoirs has received limited attention. We measured dissolved oxygen, pH and water temperature in the Lake Kar apiro hydroreservoir, northern New Zealand, across a gradient of proportional water-column height occupied by the invasive macrophytes Egeria densa and Ceratophyllum demersum, which dominated in the upperriverine (variable water inflow) and lower-lacustrine (variable water level) sections, respectively. Hypoxia and anoxia events that occurred inside invasive macrophyte beds during their summer peak biomass accumulation period were more pronounced for C. demersum than for E. densa, and within the bottom 20% of the water column. In contrast, pH and temperature changed little in relation to proportional macrophyte height. Macrophyte species differences in the production of hypoxia and anoxia events increased when site-specific hydropeaking management covariates (depth, inflows, water level) were accounted for. This association with hydropeaking likely resulted from contrasting hydrodynamics in the lower-lacustrine and upper-riverine lake sections, where oxygen can decrease with higher water levels and lower water inflow rates, respectively. During the course of our study, some macrophyte beds were treated with herbicide, enabling us to document prolonged and sustained hypoxic/anoxic conditions near the bottom following spraying. These results underscore the adverse effects of invasive macrophytes on water physicochemical attributes that sustain aquatic biota, and highlight the context-dependent nature of these effects moderated by reservoir management for hydropeaking and macrophyte control.

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Section: Spatial Scales Of Invasive Macrophyte Effectsmentioning

confidence: 65%

Invasive macrophytes induce context‐specific effects on oxygen, pH, and temperature in a hydropeaking reservoir

Moore

Clearwater²,

Duggan

et al. 2020

River Research & Apps

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“…ponds isolated from other waterways, large dead zones stretching hundreds of kilometres) (Diaz, 2001;Diaz and Rosenberg, 2008). Animals can also be exposed to intermittent cycles of hypoxia, in which bouts of low O 2 are separated by periods of normoxia (or even hyperoxia), as is common in tide pools, estuaries, coral reefs and heavily vegetated systems (Andersen et al, 2017;Breitburg, 1992;Diaz, 2001;Nilsson and Renshaw, 2004;Richards, 2011;Tyler et al, 2009). Instances of both constant hypoxia and intermittent hypoxia are well documented in aquatic environments, but the biological effects of the latter have received comparably little attention.…”

Section: Introductionmentioning

confidence: 99%

Distinct metabolic adjustments arise from acclimation to constant hypoxia and intermittent hypoxia in estuarine killifish (Fundulus heteroclitus)

Borowiec

McClelland

Rees

et al. 2018

Journal of Experimental Biology

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Many fish experience daily cycles of hypoxia in the wild, but the physiological strategies for coping with intermittent hypoxia are poorly understood. We examined how killifish adjust O 2 supply and demand during acute hypoxia, and how these responses are altered after prolonged acclimation to constant or intermittent patterns of hypoxia exposure. We acclimated killifish to normoxia (∼20 kPa O 2), constant hypoxia (2 kPa) or intermittent cycles of nocturnal hypoxia (12 h:12 h normoxia:hypoxia) for 28 days, and then compared whole-animal O 2 consumption rates (Ṁ O2) and tissue metabolites during exposure to 12 h of hypoxia followed by reoxygenation in normoxia. Normoxiaacclimated fish experienced a pronounced 27% drop in Ṁ O2 during acute hypoxia, and modestly increased Ṁ O2 upon reoxygenation. They strongly recruited anaerobic metabolism during acute hypoxia, indicated by lactate accumulation in plasma, muscle, liver, brain, heart and digestive tract, as well as a transient drop in intracellular pH, and they increased hypoxia inducible factor (HIF)-1α protein abundance in muscle. Glycogen, glucose and glucose-6-phosphate levels suggested that glycogen supported brain metabolism in hypoxia, while the muscle used circulating glucose. Acclimation to constant hypoxia caused a stable ∼50% decrease in Ṁ O2 that persisted after reoxygenation, with minimal recruitment of anaerobic metabolism, suggestive of metabolic depression. By contrast, fish acclimated to intermittent hypoxia maintained sufficient O 2 transport to support normoxic Ṁ O2 , modestly recruited lactate metabolism and increased Ṁ O2 dramatically upon reoxygenation. Both groups of hypoxia-acclimated fish had similar glycogen, ATP, intracellular pH and HIF-1α levels as normoxic controls. We conclude that different patterns of hypoxia exposure favour distinct strategies for matching O 2 supply and O 2 demand.

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“…Freshwaters are important components of regional and global carbon budgets (Duarte and Prairie, 2005;Raymond et al, 2013). Lakes in particular have received attention as hotspots of carbon cycling emitting CO 2 and CH 4 to the atmosphere (Tranvik et al, 2009;Holgerson and Raymond, 2016;Bastviken et al, 2011;Wik et al, 2016). However, the role and magnitude of carbon emissions from lakes remain uncertain as the estimated gas fluxes often depend on empirical models of gas exchange velocity with substantial uncertainty.…”

Section: Introductionmentioning

confidence: 99%

“…The influence of convection on gas exchange velocity and the resulting gas flux may thus be missed if not accounted for (Holgerson et al, 2016;Podgrajsek et al, 2015). Small lakes (< 0.01 km 2 ) are globally abundant and may comprise up to 20 % of the total surface area of lakes (Holgerson and Raymond, 2016) and extensive changes in CO 2 concentrations and vertical mixing make single or even several daytime measurements of CO 2 fluxes insufficient to calculate daily fluxes (Holgerson et al, 2016;Andersen et al, 2017). Increasing the temporal resolution and measuring gas flux during day and night time would enable better models of gas exchange velocity and large-scale carbon budgets.…”

Section: Introductionmentioning

confidence: 99%

Technical note: A simple and cost-efficient automated floating chamber for continuous measurements of carbon dioxide gas flux on lakes

2018

Self Cite

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Abstract. Freshwaters emit significant amounts of CO2 on a global scale. However, emissions remain poorly constrained from the diverse range of aquatic systems. The drivers and regulators of CO2 gas flux from standing waters require further investigation to improve knowledge on both global-scale estimates and system-scale carbon balances. Often, lake–atmosphere gas fluxes are estimated from empirical models of gas transfer velocity and air–water concentration gradient. Direct quantification of the gas flux circumvents the uncertainty associated with the use of empirical models from contrasting systems. Existing methods to measure CO2 gas flux are often expensive (e.g. eddy covariance) or require a high workload in order to overcome the limitations of single point measurements using floating chambers. We added a small air pump, a timer and an exterior tube to ventilate the floating chamber headspace and passively regulate excess air pressure. By automating evacuation of the chamber headspace, continuous measurements of lake CO2 gas flux can be obtained with minimal effort. We present the chamber modifications and an example of operation from a small forest lake. The modified floating chamber performed well in the field and enabled continuous measurements of CO2 gas flux with 40 min intervals. Combining the direct measurements of gas flux with measurements of air and waterside CO2 partial pressure also enabled calculation of gas exchange velocity. Building and using the floating chamber is straightforward. However, because an air pump is used to restart measurements by thinning the chamber headspace with atmospheric air, the duration of the air pump pause–pulse cycle is critical and should be adjusted depending on system characteristics. This may result in shorter deployment duration, but this restriction can be circumvented by providing a stronger power source. The simple design makes modifications of the chamber dimensions and technical additions for particular applications and systems easy. This should make this approach to measuring gas flux flexible and appropriate in a wide range of different systems.

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Extreme diel dissolved oxygen and carbon cycles in shallow vegetated lakes

Cited by 73 publications

References 46 publications

Invasive macrophytes induce context‐specific effects on oxygen, pH, and temperature in a hydropeaking reservoir

Invasive macrophytes induce context‐specific effects on oxygen, pH, and temperature in a hydropeaking reservoir

Distinct metabolic adjustments arise from acclimation to constant hypoxia and intermittent hypoxia in estuarine killifish (Fundulus heteroclitus)

Technical note: A simple and cost-efficient automated floating chamber for continuous measurements of carbon dioxide gas flux on lakes

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