24 results on '"Meire, Patrick"'
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2. Silicon Affects Nutrient Content and Ratios of Wetland Plants
- Author
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Schaller, Jörg, Schoelynck, Jonas, Struyf, Eric, and Meire, Patrick
- Published
- 2016
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3. Resistance and reconfiguration of natural flexible submerged vegetation in hydrodynamic river modelling
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Verschoren, Veerle, Meire, Dieter, Schoelynck, Jonas, Buis, Kerst, Bal, Kris D, Troch, Peter, Meire, Patrick, and Temmerman, Stijn
- Published
- 2016
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4. Trade-off between drag reduction and light interception of macrophytes: comparing five aquatic plants with contrasting morphology
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Bal, Kris D., Bouma, Tjeerd J., Buis, Kerst, Struyf, Eric, Jonas, Schoelynck, Backx, Hans, and Meire, Patrick
- Published
- 2011
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5. Silica uptake in aquatic and wetland macrophytes: a strategic choice between silica, lignin and cellulose?
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Schoelynck, Jonas, Bal, Kris, Backx, Hans, Okruszko, Tomasz, Meire, Patrick, and Struyf, Eric
- Published
- 2010
6. Input, behaviour and distribution of multiple elements in abiotic matrices along a transect within the Okavango Delta, northern Botswana
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Schaller, Jörg, Schoelynck, Jonas, Murray-Hudson, Mike, Frings, Patrick J., van Pelt, Dimitri, Hegewald, Tilo, Mosimane, Keotshephile, Gondwe, Mangaliso, Wolski, Piotr, Meire, Patrick, and Struyf, Eric
- Published
- 2016
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7. Environmental control of macrophyte traits and interactions with metabolism and hydromorphology in a groundwater‐fed river.
- Author
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Reitsema, Rosanne E., Preiner, Stefan, Meire, Patrick, Hein, Thomas, Dai, Yanran, and Schoelynck, Jonas
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FLOW velocity ,PLANT morphology ,MACROPHYTES ,PLANT biomass ,WATER depth ,METABOLISM ,LEAF area - Abstract
Macrophytes are important organisms in running water systems, having a decisive role in ecological processes and interactions. Their temporal and spatial distribution in streams can be highly variable, and this is often determined by flow velocity. In this study, macrophyte growth, morphology and nutrient stoichiometry were studied monthly during one growing season in reaches with different flow velocity and flow velocity distribution and, as a result, different distributional plant patterns in an Austrian lowland stream, dominated by evergreen macrophyte species, Berula erecta. Flow velocity, water depth, fine sediment layer depth and metabolism were measured in the stream and the correlation with plant biomass and morphological traits was tested. We aimed to study differences between reaches with different distributional plant patterns and whether common interactions between macrophytes and flow velocity can also be observed when vegetation is evergreen. Plant biomass showed seasonal variation, with the highest values in June and the lowest in February. In the reach with low flow velocity and homogeneous macrophyte distribution, biomass peaked in summer and plant morphology changed with the seasons, whereas biomass and morphology in the reach with high flow velocity and patchy distribution were more constant throughout the year. Plant carbon, nitrogen and phosphorus content were higher in spring and autumn than in summer, whereas biogenic silica accumulated over the course of the growth season. Stream metabolism was strongly correlated with macrophyte biomass, and this correlation was stronger in the reach with homogeneous macrophyte distribution than in the reach with a patchy distribution. Moreover, average leaf area and stem length were positively correlated with fine sediment layer depth, and negatively with flow velocity. The results stress the importance of macrophyte growth and morphology in river processes like metabolism, hydromorphology and nutrient dynamics: especially plant morphology plays an important role in macrophyte–flow interactions. [ABSTRACT FROM AUTHOR]
- Published
- 2021
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8. The Future of Freshwater Macrophytes in a Changing World: Dissolved Organic Carbon Quantity and Quality and Its Interactions With Macrophytes.
- Author
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Reitsema, Rosanne E., Meire, Patrick, and Schoelynck, Jonas
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MACROPHYTES ,CARBON compounds ,AQUATIC ecology - Abstract
Freshwater ecosystems are confronted with the effects of climate change. One of the major changes is an increased concentration of aquatic carbon. Macrophytes are important in the aquatic carbon cycle and play as primary producers a crucial role in carbon storage in aquatic systems. However, macrophytes are affected by increasing carbon concentrations. The focus of this review lies on dissolved organic carbon (DOC), one of the most abundant forms of carbon in aquatic ecosystems which has many effects on macrophytes. DOC concentrations are rising; the exact cause of this increase is not known, although it is hypothesized that climate change is one of the drivers. The quality of DOC is also changing; for example, in urban areas DOC composition is different from the composition in natural watersheds, resulting in DOC that is more resistant to photo-degradation. Plants can benefit from DOC as it attenuates UV-B radiation, it binds potentially harmful heavy metals and provides CO
2 as it breaks down. Yet plant growth can also be impaired under high DOC concentrations, especially by humic substances (HS). HS turn the water brown and attenuate light, which limits macrophyte photosynthesis at greater depths. This leads to lower macrophyte abundance and lower species diversity. HS form a wide class of chemicals with many different functional groups and they therefore have the ability to interfere with many biochemical processes that occur in freshwater organisms. Few studies have looked into the direct effects of HS on macrophytes, but there is evidence that HS can interfere with photosynthesis by entering macrophyte cells and causing damage. DOC can also affect reactivity of heavy metals, water and sediment chemistry. This indirectly affects macrophytes too, so they are exposed to multiple stressors that may have contradictive effects. Finally, macrophytes can affect DOC quality and quantity as they produce DOC themselves and provide a substrate to heterotrophic bacteria that degrade DOC. Because macrophytes take a key position in the aquatic ecosystem, it is essential to understand to what extent DOC quantity and quality in surface water are changing and how this will affect macrophyte growth and species diversity in the future. [ABSTRACT FROM AUTHOR]- Published
- 2018
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9. The role of macrophyte structural complexity and water flow velocity in determining the epiphytic macroinvertebrate community composition in a lowland stream.
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Wolters, Jan-Willem, Verdonschot, Ralf C. M., Schoelynck, Jonas, Verdonschot, Piet F. M., and Meire, Patrick
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INVERTEBRATES ,MACROPHYTES ,CALLITRICHE ,AQUATIC plants ,RIVERS ,FLOW velocity - Abstract
Habitat structural complexity provided by aquatic macrophytes in lowland streams affects the associated epiphytic macroinvertebrate assemblages in both direct (increased microhabitat diversity, refuge against predation) and indirect ways (e.g. current attenuation by physical structures). In a correlative field study carried out in two different years in a Belgian stream, we investigated the effects of the factors macrophyte identity, macrophyte complexity (represented as fractal complexity) and current velocity on the composition of the macroinvertebrate community associated with monospecific macrophyte patches, consisting of plants with differing structural complexity; Sparganium emersum Rehmann (least complex), Potamogeton natans L. (intermediate) and Callitriche obtusangula Le Gall (most complex). In addition to significantly lower within-patch current velocity being observed, vegetation stands consisting of complex macrophytes also harboured significantly richer macroinvertebrate communities than stands of simpler macrophytes. A significant part of the variation in the macroinvertebrate community composition could be explained by plant identity, macrophyte complexity and current velocity. However, it was not possible to determine the relative importance of these three factors, because of their high degree of intercorrelation. Additionally, the explanatory power of these factors was higher under conditions of high current velocity, suggesting a role of macrophyte patches as instream flow refugia for macroinvertebrates. [ABSTRACT FROM AUTHOR]
- Published
- 2018
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10. What is a macrophyte patch? Patch identification in aquatic ecosystems and guidelines for consistent delineation.
- Author
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Schoelynck, Jonas, Creëlle, Stéphan, Buis, Kerst, De Mulder, Tom, Emsens, Willem-Jan, Hein, Thomas, Meire, Dieter, Meire, Patrick, Okruszko, Tomasz, Preiner, Stefan, Roldan Gonzalez, Rebeca, Silinski, Alexandra, Temmerman, Stijn, Troch, Peter, Van Oyen, Tomas, Verschoren, Veerle, Visser, Fleur, Wang, Chen, Wolters, Jan-Willem, and Folkard, Andrew
- Abstract
Patches are of central interest to many areas of environmental science because they provide a lower limit of structural detail in synoptic studies, and an upper limit of contextual structure for point measurement-based studies. Identification and delineation of macrophyte patches however, is often arbitrary and case-specific. In this paper we propose a widely-applicable set of guidelines for delineating a “patch” and “patch matrix” – the latter implying a collection of interacting patches – which could standardise future research. To support this proposal, we examine examples from eco-hydrological studies, focusing on interactions between plants, water flow, sediment, and invertebrates. We discuss three aspects that are key to the delineation of a patch: (1) constitution (variable(s) whose values define the patch), (2) spatial properties (patch boundaries), and (3) distinction (of isolated single patches from multiple separate-but-interacting patches). The discussion of these aspects results in guidelines for identifying and delineating a patch which is applicable to any aquatic habitat, and covers a broad range of disciplines such as plant and animal ecology, biogeochemistry, hydraulics, and sedimentology. [ABSTRACT FROM AUTHOR]
- Published
- 2018
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11. Experimental flume study on Potamogeton natans and Ranunculus fluitans macrophytes: impact of hydrodynamics on 15N-ammonium uptake rates
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Woule Ebongue, Véronique, Brion, Nathalie, Hove, Nathalie, Barron, Cristina, Dehairs, Frank, Bal, K., Bouma, Tjeerd, Schoelynck, Jonas, De Deckere, Erik, Meire, Patrick, Earth System Sciences, Analytical and Environmental Chemistry, and Chemistry
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flume ,ammonium ,nutrients ,15N ,hydraulics ,turbulence ,potamogeton natans ,Flow Velocity ,rivers ,ranunculus fluitans ,macrophytes - Abstract
By means of incubations in a flume tank using 15N enriched ammonium label we investigate the concomitant effects of (i) different morphologies and specific surfaces, (ii) bulk water flow successively set at 0.3 and 0.1 m s-1 and (iii) three patch configurations on the rates of 15N-ammonium uptake rates for two macrophytes species: Potamogeton natans and Ranunculus fluitans. Because recent studies have shown that the rate of ammonium uptake by seagrass specimens depends on hydrodynamic factors such as shear stress and turbulence -which notably influence the rate at which ammonium is delivered to the surface of the leaves- these incubations were performed together with high resolution flow velocity measurements. Results of our experiments show higher 15N-ammonium uptake rates at the edges of patches in some of the incubations involving the two species. Currents and turbulence which are supposed to be the highest at the edges of the patches can explain these patterns. R. fluitans showing the highest specific surface of the two species is also the most efficient at obtaining 15N-ammonium from the water column in all experimental conditions. Results also show enhanced 15N-ammonium uptake rates with increased bulk water flow for both species. This result which is consistent with that of previous studies on seagrass communities is explained by turbulent energy and stresses factors that increase both advection of nutrients through the community and rates of diffusion at the surfaces of the specimens as flow velocity increases. Finally, flume configuration only affects uptake rates for R. fluitans at lower bulk flow velocity (0.1 m s-1). Higher 15N-ammonium uptake rates are observed for this species in the configuration when the flume is half filled compare to the configuration when the flume fully filled with both species. No significant difference is observed between the two configurations for P. natans. Our findings provide an improved insight in the concomitant effects of factors and processes occurring in streaming rivers on the nitrogen uptake by the two studied macrophytes. This is essential for incorporating the role of macrophytes in the scope of integrated water management and for furthering knowledge of the structure and functioning
- Published
- 2010
12. The trapping of organic matter within plant patches in the channels of the Okavango Delta: a matter of quality.
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Schoelynck, Jonas, Schaller, Jörg, Murray-Hudson, Mike, Frings, Patrick, Conley, Daniel, van Pelt, Dimitri, Mosimane, Keotshephile, Gondwe, Mangaliso, Wolski, Piotr, Meire, Patrick, and Struyf, Eric
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ORGANIC compounds & the environment ,WETLANDS ,MACROPHYTES ,MINERALIZATION ,ENVIRONMENTAL engineering - Abstract
The role of in-stream aquatic vegetation as ecosystem engineers in the distribution of organic matter was investigated in the Okavango Delta, one of the world's largest oligotrophic wetlands. The Okavango channel beds are covered up to 50% with submerged macrophyte patches. By accumulating and concentrating organic matter in the sediments below the patches, macrophytes are likely able to locally forestall a deficiency of nutrients. Up to 21 times more N, 18 times more C, 13 times more P and 6 times more Si can be found in vegetated sediments compared to non-vegetated sediments. Nutrient specific accumulation relates to its relative scarcity in the overlaying water. There is a depletion of dissolved N relative to P, whereas Si is relatively abundant. The Okavango Delta water can generally be characterised as oligotrophic based on plant species composition (e.g. presence of carnivorous plants and absence of floating plants), low plant N:P ratios, and low nutrient- and element-concentrations. Local mineralization and intensified nutrient cycling in the sediments is hypothesized to be crucial for the macrophytes' survival because it provides a key source of the essential nutrients which plants otherwise cannot obtain in sufficient quantities from the nutrient poor water. By engineering the ecosystem as such, channel vegetation also retards the loss of elements and nutrients to island groundwater flow, contributing to one of the key processes driving the high productivity of the Okavango Delta, making it unique among its kind. [ABSTRACT FROM AUTHOR]
- Published
- 2017
- Full Text
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13. Depth Estimation of Submerged Aquatic Vegetation in Clear Water Streams Using Low-Altitude Optical Remote Sensing.
- Author
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Visser, Fleur, Buis, Kerst, Verschoren, Veerle, and Meire, Patrick
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DRONE aircraft ,AQUATIC plants ,OPTICAL remote sensing ,BATHYMETRY ,MACROPHYTES - Abstract
UAVs and other low-altitude remote sensing platforms are proving very useful tools for remote sensing of river systems. Currently consumer grade cameras are still the most commonly used sensors for this purpose. In particular, progress is being made to obtain river bathymetry from the optical image data collected with such cameras, using the strong attenuation of light in water. No studies have yet applied this method to map submergence depth of aquatic vegetation, which has rather different reflectance characteristics from river bed substrate. This study therefore looked at the possibilities to use the optical image data to map submerged aquatic vegetation (SAV) depth in shallow clear water streams. We first applied the Optimal Band Ratio Analysis method (OBRA) of Legleiter et al. (2009) to a dataset of spectral signatures from three macrophyte species in a clear water stream. The results showed that for each species the ratio of certain wavelengths were strongly associated with depth. A combined assessment of all species resulted in equally strong associations, indicating that the effect of spectral variation in vegetation is subsidiary to spectral variation due to depth changes. Strongest associations (R
2 -values ranging from 0.67 to 0.90 for different species) were found for combinations including one band in the near infrared (NIR) region between 825 and 925 nm and one band in the visible light region. Currently data of both high spatial and spectral resolution is not commonly available to apply the OBRA results directly to image data for SAV depth mapping. Instead a novel, low-cost data acquisition method was used to obtain six-band high spatial resolution image composites using a NIR sensitive DSLR camera. A field dataset of SAV submergence depths was used to develop regression models for the mapping of submergence depth from image pixel values. Band (combinations) providing the best performing models (R2 -values up to 0.77) corresponded with the OBRA findings. A 10% error was achieved under sub-optimal data collection conditions, which indicates that the method could be suitable for many SAV mapping applications. [ABSTRACT FROM AUTHOR]- Published
- 2015
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14. Design and evaluation of a multifunctional plate sediment trap suitable for subaqueous and floodplain environments.
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Schoelynck, Jonas, Oosterlee, Lotte, De Groote, Toon, Maris, Tom, Struyf, Eric, Meire, Patrick, and Temmerman, Stijn
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UNDERWATER pipelines ,FLOODPLAIN ecology ,BIOGEOMORPHOLOGY ,MARINE sediments ,FILTER paper ,VEGETATION dynamics ,WETLAND ecology ,AQUATIC biodiversity - Abstract
In recent years, it has become increasingly clear that two-way interactions between organisms and landscape-forming processes play a key role in the evolution of many aquatic ecosystems. To be able to compare sedimentation processes among different environments, a standardized method that is generally applicable is necessary. Current methods are usually designed for one environment only or are unreliable in the presence of vegetation. This paper presents the functionality of a plate sediment trap with a lid in combination with a filter paper, which enables the measurement of sedimentation rates in both permanently subaqueous environments and periodically flooded wetlands. We first present the trap design and demonstrate its functionality. No significant differences were found between replicates, nor was there any indication of a trap size effect on the sedimentation rate. Secondly, we demonstrate its applicability in periodically flooded and permanently subaqueous environments and in the presence or absence of vegetation. It is concluded that the use of a standardized method and equipment makes it possible to compare (bio)geomorphological changes in totally different environments. Copyright © 2014 John Wiley & Sons, Ltd. [ABSTRACT FROM AUTHOR]
- Published
- 2015
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15. Thigmomorphogenetic responses of an aquatic macrophyte to hydrodynamic stress.
- Author
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Schoelynck, Jonas, Puijalon, Sara, Meire, Patrick, and Struyf, Eric
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MACROPHYTES ,EFFECT of stress on plants ,THIGMOMORPHOGENESIS ,PLANT diversity ,EGERIA densa ,CELLULOSE ,TENSILE strength - Abstract
The response of aquatic plants to abiotic factors is a crucial study topic, because the diversity of aquatic vegetation is strongly related to specific adaptations to a variety of environments. This biodiversity ensures resilience of aquatic communities to new and changing ecological conditions. In running water, hydrodynamic disturbance is one of the key factors in this context. While plant adaptations to resource stress (nutrients, light...) are well documented, adaptations to mechanical stress, particularly flow, are largely unknown. The submerged species Egeria densa was used in an experiment to detect whether the presence or absence of hydrodynamic stress causes plant thigmomorphogenetic responses (i) in terms of plant biogenic silica (BSi), cellulose and lignin concentrations, and (ii) in terms of plant strength. Plant silica concentrations, as well as lignin concentrations were significantly higher in presence of hydrodynamic stress. These physiological changes are accompanied by some significant changes in stem biomechanical traits: stem resistance to tensile forces (breaking force and breaking strength) and stiffness were higher for plants exposed to hydrodynamic stress. We conclude that the response of this aquatic plant species to mechanical stress is likely the explaining factor for a higher capacity to tolerate stress through the production of mechanically hardened shoots. [ABSTRACT FROM AUTHOR]
- Published
- 2015
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16. Different morphology of Nuphar lutea in two contrasting aquatic environments and its effect on ecosystem engineering.
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Schoelynck, Jonas, Bal, Kris, Verschoren, Veerle, Penning, Ellis, Struyf, Eric, Bouma, Tjeerd, Meire, Dieter, Meire, Patrick, and Temmerman, Stijn
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NUPHAR lutum ,MACROPHYTES ,PLANT morphology ,ECOSYSTEM dynamics ,BIOMASS ,GEOMORPHOLOGY ,HYDRAULICS - Abstract
ABSTRACT Aquatic plants (macrophytes) can have a large effect on river hydraulics and geomorphology. Though, the extent to how plant morphological plasticity actively influences these feedbacks has received little scientific attention. The nymphaeid macrophyte species Nuphar lutea (L.) Smith is characterized by a distinct leaf duality. Floating leaves shade most of the submerged leaves thereby limiting light penetration in the water. Despite their apparent negligible photosynthetic role, submerged leaves of N. lutea remain intact during summer and contribute a significant part to the total biomass. Our results indicate that the submerged leaves are crucial in plant-flow interactions and hence in the engineering potential of the plant, i.e. the capacity to locally reduce flow velocities and to promote sedimentation, including organic matter deposition. Plant individuals growing in running river water were compared to individuals from adjacent oxbow lake water. The number and size of submerged leaves were significantly higher for river standing individuals and the accumulated sediment contained significantly more organic matter, total nitrogen and total phosphorus, and was characterized by a lower carbon/nitrogen ratio and a finer grain size. We therefore argue that the submerged N. lutea canopy in rivers has the ability to create a high-nutrient, low hydrodynamic environment, resembling the conditions found in oxbow lakes. Copyright © 2014 John Wiley & Sons, Ltd. [ABSTRACT FROM AUTHOR]
- Published
- 2014
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17. Economic valuation of ecosystem services, a case study for aquatic vegetation removal in the Nete catchment (Belgium).
- Author
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Boerema, Annelies, Schoelynck, Jonas, Bal, Kris, Vrebos, Dirk, Jacobs, Sander, Staes, Jan, and Meire, Patrick
- Abstract
Abstract: In the last decades, lowland rivers were forced to drain larger water quantities during ever shorter time periods. This is mainly caused by current and historic land-use changes (e.g. increase of built area) and increased intensification of agriculture practices (e.g. drainage). River flow, however, is hampered by human artefacts such as weirs and dams as well as by naturally occurring aquatic vegetation. To avoid flooding and water related problems, river managers opt to remove aquatic vegetation. According to the European Water Framework Directive (2000/60/EC), all costs of water management should be charged for (full cost recovery requirement). This study aims to assess whether or not this is achieved in case of aquatic vegetation removal. This method is illustrated through a case study of the Nete Catchment, Belgium. Results show that flood control benefits exceed costs by only a small amount in wet years, but costs exceed benefits in dry years. If decision makers account for even a few ecosystem services, the costs of vegetation removal exceed the benefits in both scenarios. Only local stakeholders in flood risk areas can benefit from aquatic vegetation removal during wet summer seasons. [Copyright &y& Elsevier]
- Published
- 2014
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18. Influence of hydraulics on the uptake of ammonium by two freshwater plants.
- Author
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Bal, Kris D., Brion, Natacha, Woulé‐Ebongué, Veronique, Schoelynck, Jonas, Jooste, Antoinette, Barrón, Cristina, Dehairs, Frank, Meire, Patrick, and Bouma, Tjeerd J.
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HYDRAULICS ,AMMONIUM ,FRESHWATER plants ,BIOGEOCHEMISTRY ,INFORMATION theory ,POTAMOGETON - Abstract
Macrophytes are important in the biogeochemistry of flowing rivers, although most information so far has relied on measurements of nutrients in plant tissues. This yields only indirect information on the nutrient uptake fluxes by roots and shoots and about nutrient translocation between roots and shoots. Here, we studied nitrogen uptake through experiments with enriched
15 N stable isotopes., Two macrophytes ( Potamogeton natans and Ranunculus fluitans) were grown in a closed race track-shaped flume, allowing us to control the hydraulic conditions in and around the plants. Overall ammonium uptake rates (μmol g−1 dry mass h−1 ) were higher for R. fluitans than P. natans., In addition to differences between the species, the spatial position of individuals within the plant patch and water flow were also important in explaining ammonium uptake. Thus, ammonium uptake was high at the leading edge of the patch and increased with velocity., Plant characteristic, such as the angle at which the plants bent in the flow, was also correlated with ammonium uptake. Differences in nutrient uptake associated with hydrodynamic parameters raised the question of how the two are related. For both species, uptake was not correlated with Reynolds stress, indicating the poor effect of turbulent mixing in determining ammonium uptake. [ABSTRACT FROM AUTHOR]- Published
- 2013
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- View/download PDF
19. Submerged macrophytes avoiding a negative feedback in reaction to hydrodynamic stress.
- Author
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Schoelynck, Jonas, Meire, Dieter, Bal, Kris, Buis, Kerst, Troch, Peter, Bouma, Tjeerd, Meire, Patrick, and Temmerman, Stijn
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MACROPHYTES ,HYDRODYNAMICS ,AQUATIC ecology ,CALLITRICHE ,SHEAR zones ,SEDIMENTATION & deposition ,RIVER channels ,PLANT growth - Abstract
Abstract: In most aquatic ecosystems, hydrodynamic conditions are a key abiotic factor determining species distribution and aquatic plant abundance. Recently, local differences in hydrodynamic conditions have been shown to be an explanatory mechanism for the patchy pattern of Callitriche platycarpa Kütz. vegetation in lowland rivers. These local conditions consists of specific areas of increased shear zones, resulting in additional plant stress and erosion of the sediment on the one hand and local decreased shear zones resulting in zones favourable to plant growth and sedimentation of bed material on the other hand. In this study, the process of this spatial plant-flow-sedimentation interaction has been illustrated quantitatively by in situ flume measurements. By disturbing the incoming discharge on a single patch in such flume, we have quantified the behaviour and influence of a C. platycarpa patch under normal field conditions (base flow). Additionally, the behaviour of a C. platycarpa patch under different conditions of hydrodynamic stress has been examined in a laboratory flume. Indeed, flexible, submerged macrophytes are capable to adapt patch dimensions with changing stream velocities. At times of modest hydrodynamic stress, the species takes a position near the water surface and optimises its leaf stand, thereby maximising its photosynthetic capacity. At times of peak discharge, the patch will bend down towards the river bed and become more confined and streamlined, as such averting the stream velocity and diminishing the risk of breaking or being uprooted. In this paper, the processes of local hydrodynamic conditions on the patch and the patch’ intriguing life strategy of avoiding negative feedback was shown. [Copyright &y& Elsevier]
- Published
- 2013
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20. Self-organised patchiness and scale-dependent bio-geomorphic feedbacks in aquatic river vegetation.
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Schoelynck, Jonas, de Groote, Toon, Bal, Kris, Vandenbruwaene, Wouter, Meire, Patrick, and Temmerman, Stijn
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SELF-organizing systems ,MACROPHYTES ,PLANT growth ,EROSION ,SEDIMENTATION & deposition ,PLANT physiology ,MERISTEMS - Abstract
Spatial self-organisation of ecosystems is the process by which large-scale ordered spatial patterns emerge from disordered initial conditions through local feedbacks between organisms and their environment. Such process is considered important for ecosystem functioning, providing increased productivity, resistance and resilience against environmental change. Although spatial self-organisation has been found for an increasing number of ecosystems, it has never been shown so far for aquatic river vegetation. Here we explore the existence of spatial self-organisation of freshwater macrophyte patches in a typical lowland river (Belgium), showing that the underlying mechanisms for pattern formation are scale-dependent feedbacks between plant growth, water flow and local river bed erosion and sedimentation. The mapping of vegetation patches showed that the frequency distribution of patch sizes is governed by a power-law function, suggesting that the patches are self-organised. Scale-dependent feedbacks, likely to lead to this self-organised pattern, were demonstrated with a mimic experiment. Both positive and negative feedbacks on plants were confirmed by a transplantation experiment. Placing vegetation patch mimics in the river showed experimentally that on a short range (within and behind the mimics) flow reduction and increased sedimentation occurred, while on a larger range (next to patches) the flow was accelerated and decreased sedimentation took place. By transplanting macrophytes within, next to and further away from existing patches, it was proven that the conditions within the patches favoured the survival and growth of transplants (i.e. short-range positive feedback), while the conditions just next to patches led to decreased survival and growth (i.e. long-range negative feedback). [ABSTRACT FROM AUTHOR]
- Published
- 2012
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- View/download PDF
21. Can Acid Volatile Sulfides (AVS) Influence Metal Concentrations in the Macrophyte Myriophyllum aquaticum?
- Author
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Teuchies, Johannes, De Jonge, Maarten, Meire, Patrick, Blust, Ronny, and Bervoets, Lieven
- Subjects
- *
PARROT'S-feather (Plant) , *EFFECT of metals on plants , *METAL sulfides , *MACROPHYTES , *BIOACCUMULATION in plants , *CONTAMINATED sediments , *HYPOXIA (Water) , *RHIZOSPHERE , *ORGANIC compounds - Abstract
The difference between the molar concentrations of simultaneously extracted metals (SEM) and acid volatile sulfides (AVS) is widely used to predict metal availability toward invertebrates in hypoxic sediments. However, this model is poorly investigated for macrophytes. The present study evaluates metal accumulation in roots and stems of the macrophyte Myriophyllum aquaticum during a 54 day lab experiment. The macrophytes, rooting in metal contaminated, hypoxic, and sulfide rich field sediments were exposed to surface water with 40% or 90% oxygen. High oxygen concentrations in the 90% treatment resulted in dissolution of the metal-sulfide complexes and a gradual increase in labile metal concentrations during the experiment. However, the general trend of increasing availability in the sediment with time was not translated in rising M. aquaticum metal concentrations. Processes at the root-sediment interface, e.g., radial oxygen loss (ROL) or the release of organic compounds by plant roots and their effect on metal availability in the rhizosphere may be of larger importance for metal accumulation than the bulk metal mobility predicted by the SEM-AVS model. [ABSTRACT FROM AUTHOR]
- Published
- 2012
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22. Opposing effects of aquatic vegetation on hydraulic functioning and transport of dissolved and organic particulate matter in a lowland river: A field experiment.
- Author
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Verschoren, Veerle, Schoelynck, Jonas, Cox, Tom, Schoutens, Ken, Temmerman, Stijn, and Meire, Patrick
- Subjects
- *
PARTICULATE matter , *MACROPHYTES , *FLOW velocity , *COEFFICIENTS (Statistics) , *RIVERS - Abstract
The presence of instream aquatic vegetation (macrophytes) has an impact on the ecological functioning of rivers through their effects on transport and retention of dissolved and particulate matter, and also on the hydraulic functioning of rivers by increasing the hydraulic resistance, which results in higher water levels and may induce an increased flooding risk. In order to unravel these opposing effects, two field studies were conducted in 2013 and 2014 in a lowland river reach of 50 m with a high initial vegetation cover (>76%). We quantified the effects of three treatments − initial vegetation, partially mowed and vegetation free − on the hydraulic functioning (hydraulic resistance) and ecological functioning (transport and retention of dissolved and particulate tracers). Firstly, the partially vegetated treatment (after partial vegetation removal) resulted in reduced hydraulic resistance compared to the vegetated treatment and in enlarged retention of particulate matter compared to the vegetation free treatments. The longitudinal dispersion and transient storage zones were similar to the vegetated treatment. Moreover, the most heterogeneous flow field was also found in these partially vegetated treatments. Secondly, the vegetation free treatments (after complete vegetation removal) had the lowest hydraulic resistance, the highest flow velocity, the highest longitudinal dispersion coefficient, the largest transient storage zone, and the lowest retention of particulate matter. Thirdly, vegetated treatments had the highest hydraulic resistance, the lowest flow velocity, the lowest longitudinal dispersion coefficient, smallest transient storage zone, and the highest retention for particulate organic matter. We conclude that partial removal of the vegetation leads to an optimal trade-off between minimizing the flow velocity and maximizing the retention of particulate organic matter while minimizing the hydraulic resistance compared to the fully vegetated and vegetation free treatment. [ABSTRACT FROM AUTHOR]
- Published
- 2017
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23. How do macrophyte distribution patterns affect hydraulic resistances?
- Author
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Bal, Kris, Struyf, Eric, Vereecken, Hans, Viaene, Peter, De Doncker, Liesbet, de Deckere, Eric, Mostaert, Frank, and Meire, Patrick
- Subjects
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MACROPHYTES , *HYDRAULICS , *BIOMASS , *WATER levels , *MOWING , *ECOSYSTEM management , *CALLITRICHE , *INVERTEBRATES - Abstract
Abstract: In eutrophic river systems, macrophytes attain high biomass with reduced drainage and increased flooding risk. To avoid these problems, water managers remove vegetation. Total removal, however, increases wash out of macro-invertebrate communities reducing the ecological value of rivers. Partial vegetation removal reduces this washout and prevents an increase in hydraulic resistance. In this, study the hydraulic performance of three partial vegetation removal patterns was tested. From the results it was seen that hydraulic resistance, expressed as Manning''s n, was varying between 0.025m−1/3 s and 0.050m−1/3 s. Compared with the empty situation, the different distribution patterns increased resistance between 14 and 23%. Hydraulic resistance of these patterns was also significantly influenced by the species present in the vegetation patches. Three groups of macrophyte plants (emerged, floating leaved and submerged) with significantly different hydraulic resistances were determined. The emerged species Sparganium erectum generated the least resistance with an average friction of 0.03m−1/3 s. Stuckenia pectinata and Potamogeton natans had slightly higher friction values around 0.4m−1/3 s. Ranunculus penicillatus and Callitriche platycarpa had average friction values around 0.05m−1/3 s. The proposed vegetation removal patterns are good alternatives to create a management system, which minimally increases hydraulic resistance but still guarantees the ecological functions. [Copyright &y& Elsevier]
- Published
- 2011
- Full Text
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24. Effects of macrophytes on ecosystem metabolism and net nutrient uptake in a groundwater fed lowland river.
- Author
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Preiner, Stefan, Dai, Yanran, Pucher, Matthias, Reitsema, Rosanne E., Schoelynck, Jonas, Meire, Patrick, and Hein, Thomas
- Abstract
Transport and transformation of inorganic nutrients are influenced by abiotic-biotic interactions and determine downstream water quality. Macrophytes play an important role in these complex ecological interactions. The role of macrophytes was studied in three reaches of the groundwater-fed, oligotrophic River Fischa with different macrophyte coverage and biomass. This was done by measuring metabolism and calculating changes in nutrient loading and concentrations, which were determined via an upstream-downstream mass balance approach. As the dominant autotrophs, we expected macrophytes (i) to have a direct effect by uptake and release, and (ii) an indirect effect by slowing down flow, which results in changed sedimentation patterns and altered conditions for heterotrophic microbial organisms implicating higher turnover and uptake rates. The seasonal development of macrophytes in 2017 had a strong impact on gross primary production, but not on ecosystem respiration. Increase in macrophyte biomass led to higher GPP (max. 5.4 g O 2 m−2d−1). ER was highest in autumn in the reach with intermediate macrophyte biomass (max. 10.1 g O 2 m−2d−1). We observed that the autotrophic uptake of phosphorus accounted for 80–145% of the P-PO 4 -flux and concluded that P-uptake by macrophytes from the sediment is an important source of phosphate for macrophytes in the river. By accumulating fine sediment, macrophytes are improving the availability of phosphate for their own long-term development. N-NO 3 , represented >99% of the nitrogen flux. N-NO 3 net uptake was higher in the reaches with more macrophytes (0.84 vs. 0.12 g m−2d−1), but in average only 21% of the net uptake could be related to autotrophic nitrogen uptake in the reach with high macrophyte biomass. Dissimilatory uptake by heterotrophic organisms, most probably denitrification, were of high relevance. Macrophytes supported microbial uptake and release by improving conditions and slowing down flow. In the River Fischa, an oligotrophic river with low variability of environmental parameters, macrophytes greatly affected nutrient uptake by direct and indirect pathways. Unlabelled Image • Macrophytes are playing a substantial role in river metabolism and net nutrient uptake • Impact of indirect effects of macrophytes (changed flow and sedimentation) are higher than direct effects (nutrient uptake) • Due to accumulation of fine sediment macrophytes maintain their main phosphorus source and improve their own habitat • By root uptake from the sediments, macrophytes enable a phosphate recycling pathway • Macrophytes enhance uptake rates of heterotrophic organisms (e.g. denitrification) [ABSTRACT FROM AUTHOR]
- Published
- 2020
- Full Text
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