473 results on '"van de Koppel J"'
Search Results
2. Spatial and temporal variation in long-term sediment accumulation in a back-barrier salt marsh
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Proceskunde, Cornacchia, L., Bakker, J. P., Koppenaal, E. C., de Groot, A. V., Olff, H., van de Koppel, J., van der Wal, D., Bouma, T. J., Proceskunde, Cornacchia, L., Bakker, J. P., Koppenaal, E. C., de Groot, A. V., Olff, H., van de Koppel, J., van der Wal, D., and Bouma, T. J.
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- 2024
3. Correction: Mussel seed is highly plastic to settling conditions: the influence of waves versus tidal emergence
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Schotanus, J, primary, Capelle, JJ, additional, Leuchter, L, additional, van de Koppel, J, additional, and Bouma, TJ, additional
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- 2023
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4. Trade-offs Related to Ecosystem Engineering: A Case Study on Stiffness of Emerging Macrophytes
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Bouma, T. J., De Vries, M. B., Low, E., Peralta, G., Tánczos, I. C., van de Koppel, J., and Herman, P. M. J.
- Published
- 2005
5. To restore coastal marine areas, we need to work across multiple habitats simultaneously
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Vozzo, M. L., primary, Doropoulos, C., additional, Silliman, B. R., additional, Steven, A., additional, Reeves, S. E., additional, ter Hofstede, R., additional, van Koningsveld, M., additional, van de Koppel, J., additional, McPherson, T., additional, Ronan, M., additional, and Saunders, M. I., additional
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- 2023
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6. Field estimates of floc dynamics and settling velocities in a tidal creek with significant along-channel gradients in velocity and SPM
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Schwarz, C., Cox, T., van Engeland, T., van Oevelen, D., van Belzen, J., van de Koppel, J., Soetaert, K., Bouma, T.J., Meire, P., and Temmerman, S.
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- 2017
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7. Alternate Stable States and Threshold Effects in Semi-Arid Grazing Systems
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Rietkerk, M. and van de Koppel, J.
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- 1997
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8. Phase-separation physics underlies new theory for the resilience of patchy ecosystems
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Siteur, K., Liu, Q-X, Rottschäfer, V., van der Heide, T., Rietkerk, M., Doelman, A., Boström, C., van de Koppel, J., Siteur, K., Liu, Q-X, Rottschäfer, V., van der Heide, T., Rietkerk, M., Doelman, A., Boström, C., and van de Koppel, J.
- Abstract
Spatial self-organization of ecosystems into large-scale (from micron to meters) patterns is an important phenomenon in ecology, enabling organisms to cope with harsh environmental conditions and buffering ecosystem degradation. Scale-dependent feedbacks provide the predominant conceptual framework for self-organized spatial patterns, explaining regular patterns observed in, e.g., arid ecosystems or mussel beds. Here, we highlight an alternative mechanism for self-organized patterns, based on the aggregation of a biotic or abiotic species, such as herbivores, sediment, or nutrients. Using a generalized mathematical model, we demonstrate that ecosystems with aggregation-driven patterns have fundamentally different dynamics and resilience properties than ecosystems with patterns that formed through scale-dependent feedbacks. Building on the physics theory for phase-separation dynamics, we show that patchy ecosystems with aggregation patterns are more vulnerable than systems with patterns formed through scale-dependent feedbacks, especially at small spatial scales. This is because local disturbances can trigger large-scale redistribution of resources, amplifying local degradation. Finally, we show that insights from physics, by providing mechanistic understanding of the initiation of aggregation patterns and their tendency to coarsen, provide a new indicator framework to signal proximity to ecological tipping points and subsequent ecosystem degradation for this class of patchy ecosystems.
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- 2023
9. Self-organized mud cracking amplifies the resilience of an iconic “Red Beach” salt marsh
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Zhang, K., Yan, J., He, Q., Xu, C., van de Koppel, J., Wang, B., Cui, B., Liu, Q.-X., Zhang, K., Yan, J., He, Q., Xu, C., van de Koppel, J., Wang, B., Cui, B., and Liu, Q.-X.
- Abstract
Self-organized patterning, resulting from the interplay of biological and physical processes, is widespread in nature. Studies have suggested that biologically triggered self-organization can amplify ecosystem resilience. However, if purely physical forms of self-organization play a similar role remains unknown. Desiccation soil cracking is a typical physical form of self-organization in coastal salt marshes and other ecosystems. Here, we show that physically self-organized mud cracking was an important facilitating process for the establishment of seepweeds in a “Red Beach” salt marsh in China. Transient mud cracks can promote plant survivorship by trapping seeds, and enhance germination and growth by increasing water infiltration in the soil, thus facilitating the formation of a persistent salt marsh landscape. Cracks can help the salt marsh withstand more intense droughts, leading to postponed collapse and faster recovery. These are indications of enhanced resilience. Our work highlights that self-organized landscapes sculpted by physical agents can play a critical role in ecosystem dynamics and resilience to climate change.
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- 2023
10. To restore coastal marine areas, we need to work across multiple habitats simultaneously
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Vozzo, M.L., Doropoulos, C., Silliman, B.R., Steven, A., Reeves, S.E., ter Hofstede, R., van Koningsveld, M., van de Koppel, J., McPherson, T., Ronan, M., Saunders, M.I., Vozzo, M.L., Doropoulos, C., Silliman, B.R., Steven, A., Reeves, S.E., ter Hofstede, R., van Koningsveld, M., van de Koppel, J., McPherson, T., Ronan, M., and Saunders, M.I.
- Abstract
Restoration of coastal marine habitats—often conducted under the umbrella of “nature-based solutions”—is one of the key actions underpinning global intergovernmental agreements, including the Paris Agreement and the 2021–2030 United Nations (UN) Decade of Restoration. To achieve global biodiversity and restoration targets, such as the Kunming–Montreal Global Biodiversity Framework, which aims to restore 30% of degraded ecosystems by 2030, we need methods that accelerate and scale up restoration activities in size and impact. Part of the solution is cross-habitat facilitation—positive interactions that occur when processes generated in one habitat benefit another. These interactions involve physical, biological, and biogeochemical processes, such as wave energy dampening, competition reduction, and nutrient cycling.
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- 2023
11. Vegetation controls on channel network complexity in coastal wetlands - Dataset
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van de Vijsel, Roeland, van Belzen, Jim, Bouma, Tjeerd, van der Wal, Daphne, Borsje, Bas W., Temmerman, Stijn, Cornacchia, L., Gourgue, Olivier, van de Koppel, J., van de Vijsel, Roeland, van Belzen, Jim, Bouma, Tjeerd, van der Wal, Daphne, Borsje, Bas W., Temmerman, Stijn, Cornacchia, L., Gourgue, Olivier, and van de Koppel, J.
- Abstract
This is the full dataset that supports the findings of the following publication: van de Vijsel, R.C., van Belzen, J., Bouma, T.J., van der Wal, D., Borsje, B.W., Temmerman, S., Cornacchia, L., Gourgue, O., van de Koppel, J. Vegetation controls on channel network complexity in coastal wetlands. Nature Communications 14, 7158 (2023). https://doi.org/10.1038/s41467-023-42731-3. The goal of this publication is to study how vegetation affects tidal channel network formation in tidal marshes. This dataset therefore contains: i) model scripts and results of a new numerical model (SFERE) for vegetation effects on tidal network formation; 2) aerial photographs of real-world tidal channel networks for comparison with modelled networks; 3) digital terrain models of real-world tidal marsh networks for comparison with modelled networks. The README-file explains the exact contents of this dataset. The SFERE model itself can also be found via GitHub (https://github.com/RCvandeVijsel/SFERE) and Zenodo (https://doi.org/10.5281/zenodo.8428792).
- Published
- 2023
12. To restore coastal marine areas, we need to work across multiple habitats simultaneously
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Vozzo, M. L. (author), Doropoulos, C. (author), Silliman, B. R. (author), Steven, A. (author), Reeves, S. E. (author), ter Hofstede, R. (author), van Koningsveld, M (author), van de Koppel, J. (author), McPherson, T. (author), Vozzo, M. L. (author), Doropoulos, C. (author), Silliman, B. R. (author), Steven, A. (author), Reeves, S. E. (author), ter Hofstede, R. (author), van Koningsveld, M (author), van de Koppel, J. (author), and McPherson, T. (author)
- Abstract
Rivers, Ports, Waterways and Dredging Engineering, Hydraulic Structures and Flood Risk
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- 2023
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13. Struggle & Emergence: On critical geometry and dynamics in tidal ecosystems
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Proceskunde, Bouma, Tjeerd, van de Koppel, J., van Belzen, Jim, Proceskunde, Bouma, Tjeerd, van de Koppel, J., and van Belzen, Jim
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- 2023
14. Long-distance facilitation of coastal ecosystem structure and resilience
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Wang, B., Zhang, K., Liu, Q.-X., Gao, Q., van de Koppel, J., Teng, S.N., Miao, X., Liu, M., Bertness, M.D., Xu, C., Wang, B., Zhang, K., Liu, Q.-X., Gao, Q., van de Koppel, J., Teng, S.N., Miao, X., Liu, M., Bertness, M.D., and Xu, C.
- Abstract
Biotic interactions that hierarchically organize ecosystems by driving ecological and evolutionary processes across spatial scales are ubiquitous in our biosphere. Biotic interactions have been extensively studied at local and global scales, but how long-distance, cross-ecosystem interactions at intermediate landscape scales influence the structure, function, and resilience of ecological systems remains poorly understood. We used remote sensing, modeling, and field data to test the hypothesis that the long-distance impact of an invasive species dramatically affects one of the largest tidal flat ecosystems in East Asia. We found that the invasion of exotic cordgrass Spartina alterniflora can produce long-distance effects on native species up to 10 km away, driving decadal coastal ecosystem transitions. The invasive cordgrass at low elevations facilitated the expansion of the native reed Phragmites australis at high elevations, leading to the massive loss and reduced resilience of the iconic Suaeda salsa “Red Beach” marshes at intermediate elevations, largely as a consequence of reduced soil salinity across the landscape. Our results illustrate the complex role that long-distance interactions can play in shaping landscape structure and ecosystem resilience and in bridging the gap between local and global biotic interactions.
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- 2022
15. Biogeomorphic modeling to assess the resilience of tidal-marsh restoration to sea level rise and sediment supply
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Gourgue, O., van Belzen, J., Schwarz, C., Vandenbruwaene, W., Vanlede, J., Belliard, J.-P., Fagherazzi, S., Bouma, T.J., van de Koppel, J., Temmerman, S., Gourgue, O., van Belzen, J., Schwarz, C., Vandenbruwaene, W., Vanlede, J., Belliard, J.-P., Fagherazzi, S., Bouma, T.J., van de Koppel, J., and Temmerman, S.
- Abstract
There is an increasing demand for the creation and restoration of tidal marshes around the world, as they provide highly valued ecosystem services. Yet restored tidal marshes are strongly vulnerable to factors such as sea level rise and declining sediment supply. How fast the restored ecosystem develops, how resilient it is to sea level rise, and how this can be steered by restoration design are key questions that are typically challenging to assess due to the complex biogeomorphic feedback processes involved. In this paper, we apply a biogeomorphic model to a specific tidal-marsh restoration project planned by dike breaching. Our modeling approach integrates tidal hydrodynamics, sediment transport, and vegetation dynamics, accounting for relevant fine-scale flow–vegetation interactions (less than 1 km2) and in the long term (several decades). Our model performance is positively evaluated against observations of vegetation and geomorphic development in adjacent tidal marshes. Model scenarios demonstrate that the restored tidal marsh can keep pace with realistic rates of sea level rise and that its resilience is more sensitive to the availability of suspended sediments than to the rate of sea level rise. We further demonstrate that restoration design options can steer marsh resilience, as they affect the rates and spatial patterns of biogeomorphic development. By varying the width of two dike breaches, which serve as tidal inlets to the restored marsh, we show that a larger difference in the width of the two inlets leads to higher biogeomorphic diversity in restored habitats. This study showcases that biogeomorphic modeling can support management choices in restoration design to optimize tidal-marsh development towards sustainable restoration goals.
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- 2022
16. Recovering wetland biogeomorphic feedbacks to restore the world’s biotic carbon hotspots
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Temmink, R.J.M., Lamers, L.P.M., Angelini, C., Bouma, T.J., Fritz, C., van de Koppel, J., Lexmond, R., Rietkerk, M., Silliman, B.R., Joosten, H., van der Heide, T., Temmink, R.J.M., Lamers, L.P.M., Angelini, C., Bouma, T.J., Fritz, C., van de Koppel, J., Lexmond, R., Rietkerk, M., Silliman, B.R., Joosten, H., and van der Heide, T.
- Abstract
Biogeomorphic wetlands cover 1% of Earth’s surface but store 20% of ecosystem organic carbon. This disproportional share is fueled by high carbon sequestration rates and effective storage in peatlands, mangroves, salt marshes, and seagrass meadows, which greatly exceed those of oceanic and forest ecosystems. Here, we review how feedbacks between geomorphology and landscape-building vegetation underlie these qualities and how feedback disruption can switch wetlands from carbon sinks into sources. Currently, human activities are driving rapid declines in the area of major carbon-storing wetlands (1% annually). Our findings highlight the urgency to stop through conservation ongoing losses and to reestablish landscape-forming feedbacks through restoration innovations that recover the role of biogeomorphic wetlands as the world’s biotic carbon hotspots.
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- 2022
17. The influence of Corophium volutator abundance on resuspension
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de Deckere, E. M. G. T., van de Koppel, J., Heip, C. H. R., Dumont, H. J., editor, Liebezeit, Gerd, editor, Dittmann, Sabine, editor, and Kröncke, Ingrid, editor
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- 2000
- Full Text
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18. Changes in diatom patch-size distribution and degradation in a spatially self-organized intertidal mudflat ecosystem
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Weerman, E. J., Van Belzen, J., Rietkerk, M., Temmerman, S., Kéfi, S., Herman, P. M. J., and Van de Koppel, J.
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- 2012
19. Biomechanical Warfare in Ecology; Negative Interactions between Species by Habitat Modification
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van Wesenbeeck, B. K., van de Koppel, J., Herman, P. M. J., Bakker, J. P., and Bouma, T. J.
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- 2007
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20. Exploration Ranges of Aka Pygmies of the Central African Republic
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Hewlett, B., van de Koppel, J. M. H., and Cavalli-Sforza, L. L.
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- 1982
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21. Fairy circles reveal the resilience of self-organized salt marshes
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Zhao, L.-X., Zhang, K., Siteur, K., Li, X.-Z., Liu, Q.-X., and van de Koppel, J.
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Spatial patterning is a fascinating theme in both theoretical and experimental ecology. It reveals resilience andstability to withstand external disturbances and environmental stresses. However, existing studies mainly focuson well-developed persistent patterns rather than transient patterns in self-organizing ecosystems. Here, combining models and experimental evidence, we show that transient fairy circle patterns in intertidal salt marshescan both infer the underlying ecological mechanisms and provide a measure of resilience. The models based onsulfide accumulation and nutrient depletion mechanisms reproduced the field-observed fairy circles, providing ageneralized perspective on the emergence of transient patterns in salt marsh ecosystems. Field experimentsshowed that nitrogen fertilization mitigates depletion stress and shifts plant growth from negative to positive inthe center of patches. Hence, nutrient depletion plays an overriding role, as only this process can explain the concentric rings. Our findings imply that the emergence of transient patterns can identify the ecological processesunderlying pattern formation and the factors determining the ecological resilience of salt marsh ecosystems
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- 2021
22. Ice needles weave patterns of stones in freezing landscapes
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Li, A., Matsuoka, N., Niu, F., Chen, J., Ge, Z., Hu, W., Li, D., Hallet, B., van de Koppel, J., Goldenfeld, N., Liu, Q.-X., Li, A., Matsuoka, N., Niu, F., Chen, J., Ge, Z., Hu, W., Li, D., Hallet, B., van de Koppel, J., Goldenfeld, N., and Liu, Q.-X.
- Abstract
Patterned ground, defined by the segregation of stones in soil according to size, is one of the most strikingly self-organized characteristics of polar and high-alpine landscapes. The presence of such patterns on Mars has been proposed as evidence for the past presence of surface liquid water. Despite their ubiquity, the dearth of quantitative field data on the patterns and their slow dynamics have hindered fundamental understanding of the pattern formation mechanisms. Here, we use laboratory experiments to show that stone transport is strongly dependent on local stone concentration and the height of ice needles, leading effectively to pattern formation driven by needle ice activity. Through numerical simulations, theory, and experiments, we show that the nonlinear amplification of long wavelength instabilities leads to self-similar dynamics that resemble phase separation patterns in binary alloys, characterized by scaling laws and spatial structure formation. Our results illustrate insights to be gained into patterns in landscapes by viewing the pattern formation through the lens of phase separation. Moreover, they may help interpret spatial structures that arise on diverse planetary landscapes, including ground patterns recently examined using the rover Curiosity on Mars.
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- 2021
23. Algal‐induced biogeomorphic feedbacks lay the groundwork for coastal wetland development
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van de Vijsel, R.C., van Belzen, J., Bouma, T.J., van der Wal, D., van de Koppel, J., van de Vijsel, R.C., van Belzen, J., Bouma, T.J., van der Wal, D., and van de Koppel, J.
- Abstract
Ecosystem establishment under adverse geophysical conditions is often studied within the “windows of opportunity” framework, identifying disturbance-free periods (e.g., calm wave climate) where species can overcome establishment thresholds. However, the role of biogeophysical interactions in this framework is less well understood. The establishment of saltmarsh vegetation on tidal flats, for example, is limited by abiotic factors such as hydrodynamics, sediment stability and drainage. On tidal flats, raised sediment ridges colonized by algal mats (Vaucheria sp.) appear to accomodate high densities of plant seedlings. Such ridges were previously found to have higher sediment strength than substratum without algae. Here, we investigate whether these measurements can be explained by geophysical factors only, or that biological (Vaucheria-induced) processes influence tidal marsh establishment by forming stabilized bedforms. We performed two experiments under controlled mesocosm conditions, to test the hypotheses that (a) Vaucheria grows better on elevated topographic relief, that (b) the binding force of their algal filaments increases sediment strength, and that (c) Vaucheria consequently creates elevated topographic relief that further facilitates algal growth. Our experimental results confirm the existence of this algal-induced biogeomorphic feedback cycle. These findings imply that benthic algae like Vaucheria may contribute significantly to tidal marsh formation by creating elevated and stabilized substratum. This suggests biogeophysical feedbacks can “widen” the windows of opportunity for further ecosystem establishment. Our results could be useful for the design of managed realignment projects aimed at restoring the unique ecosystem services of coastal wetlands, such as habitat biodiversity, carbon sequestration potential and nature-based flood defense.
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- 2021
24. Feedbacks between hydrodynamics and cold-water coral mound development
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van der Kaaden, A.-S., Mohn, C., Gerkema, T., Maier, S.R., de Froe, E., van de Koppel, J., Rietkerk, M., Soetaert, K., van Oevelen, D., van der Kaaden, A.-S., Mohn, C., Gerkema, T., Maier, S.R., de Froe, E., van de Koppel, J., Rietkerk, M., Soetaert, K., and van Oevelen, D.
- Abstract
Cold-water corals rely on currents to transport food towards them and when external conditions are favourable, they can form coral mounds. These structures, which can be over 300 m high, influence the hydrodynamics around the reefs that grow on the mounds, which feeds back to affect coral- and therefore mound-growth. We investigated these feedbacks at the Logachev coral mound province, by running simulations with a 3D hydrodynamic model (Roms-Agrif), using different seafloor bathymetries that represent consecutive stages of mound development. Simulations ranged from a fully smoothened bathymetry without mounds, to a coral mound (Haas mound) at 1.5 times its current size. The effect of mound height on coral growth was investigated by looking at the baroclinic (internal) tide, turbulent energy dissipation, vertical velocities, and horizontal bottom currents. The simulations suggest that with increasing mound height horizontal velocities increase, while turbulent energy dissipation and vertical velocities around the mound foot decrease. This supposedly limits coral growth at the mound foot and hence lateral mound extension in later stages of development. An increase in turbulent energy dissipation and vertical velocities on the mound top and upper flanks, indicates vertical mound growth at all subsequent stages. Our findings of continued vertical mound growth provide an explanation for recently published data on benthic cover from a transect over Haas mound, that show a dominance of live corals on the mound top. We find areas of increased energy conversion rates from the barotropic (surface) to the baroclinic tide on the bathymetry where we artificially eliminated the mounds from (i.e. smoothened bathymetry). Interestingly, these areas overlap with the region where coral mounds are located at present. So, the baroclinic tide is likely an important mechanism in the process of coral mound establishment. Given the relative ease with which the energy conversion rate from t
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- 2021
25. Salt marsh establishment in poorly consolidated muddy systems: effects of surface drainage, elevation, and plant age
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Cao, H., Zhu, Z., van Belzen, J., Gourgue, O., van de Koppel, J., Temmerman, S., Herman, P.M.J., Zhang, L., Yuan, L., Bouma, T.J., Cao, H., Zhu, Z., van Belzen, J., Gourgue, O., van de Koppel, J., Temmerman, S., Herman, P.M.J., Zhang, L., Yuan, L., and Bouma, T.J.
- Abstract
Conservation and restoration of salt marsh ecosystems are becoming increasingly important because of the many ecosystem services they provide. However, the processes controlling salt marsh establishment and persistence, especially on bare tidal flats in muddy areas, remain unclear. As muddy sediments typically experience a restriction of soil drainage, we expect that a surface drainage relief due to a heterogeneity topography, as might occur on the edge of tidal channels, can facilitate the establishment of salt marsh vegetation on muddy tidal flats. By means of a manipulative field experiment, using “Mega-Marsh Organ” mesocosms, we investigated the impact of surface drainage and elevation relative to mean sea level on (1) the survival of Spartina anglica seedlings from three different age classes: 1-yr, 3-month, and 1-week; and (2) the growth performance of mature S. anglica marsh tussocks. S. anglica seedling survival, especially in the establishment phase, was positively affected by better surface drainage, increases of seedling age, and higher elevation relative to mean sea level. That is, the survival rate of S. anglica seedlings at the end of 6th week increased from 0% (at surface water undrained, 1-week, 0 cm elevation) to 94.44% (at surface water drained, 1-yr, 90 cm elevation). In contrast, surface drainage did not affect the performance of large S. anglica marsh tussocks, as only increased elevation relative to mean sea level was shown to affect S. anglica tussock growth in terms of plant height, shoot numbers, and dry biomass. Based on our findings, we proposed a conceptual model to understand how surface drainage-driven feedbacks in a heterogeneous topography may be reinforced to induce salt marsh establishment in muddy systems. Further testing of present hypothesized model would be beneficial for insights into salt marsh establishment on tidal mudflats.
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- 2021
26. An invasive species erodes the performance of coastal wetland protected areas
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Ren, J., Chen, J., Xu, C., van de Koppel, J., Thomsen, M.S., Qiu, S., Cheng, F., Song, W., Liu, Q.-X., Bai, J., Zhang, Y., Cui, B., Bertness, M.D., Silliman, B.R., Li, B., He, Q., Ren, J., Chen, J., Xu, C., van de Koppel, J., Thomsen, M.S., Qiu, S., Cheng, F., Song, W., Liu, Q.-X., Bai, J., Zhang, Y., Cui, B., Bertness, M.D., Silliman, B.R., Li, B., and He, Q.
- Abstract
The world has increasingly relied on protected areas (PAs) to rescue highly valued ecosystems from human activities, but whether PAs will fare well with bioinvasions remains unknown. By analyzing three decades of seven of the largest coastal PAs in China, including World Natural Heritage and/or Wetlands of International Importance sites, we show that, although PAs are achieving success in rescuing iconic wetlands and critical shorebird habitats from once widespread reclamation, this success is counteracted by escalating plant invasions. Plant invasions were not only more extensive in PAs than non-PA controls but also undermined PA performance by, without human intervention, irreversibly replacing expansive native wetlands (primarily mudflats) and precluding successional formation of new native marshes. Exotic species are invading PAs globally. This study across large spatiotemporal scales highlights that the consequences of bioinvasions for humanity’s major conservation tool may be more profound, far reaching, and critical for management than currently recognized.
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- 2021
27. A large invasive consumer reduces coastal ecosystem resilience by disabling positive species interactions
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Hensel, M.J.S., Silliman, B.R., van de Koppel, J., Hensel, E., Sharp, S.J., Crotty, S.M., Byrnes, J.E.K., Hensel, M.J.S., Silliman, B.R., van de Koppel, J., Hensel, E., Sharp, S.J., Crotty, S.M., and Byrnes, J.E.K.
- Abstract
Invasive consumers can cause extensive ecological damage to native communities but effects on ecosystem resilience are less understood. Here, we use drone surveys, manipulative experiments, and mathematical models to show how feral hogs reduce resilience in southeastern US salt marshes by dismantling an essential marsh cordgrass-ribbed mussel mutualism. Mussels usually double plant growth and enhance marsh resilience to extreme drought but, when hogs invade, switch from being essential for plant survival to a liability; hogs selectively forage in mussel-rich areas leading to a 50% reduction in plant biomass and slower post-drought recovery rate. Hogs increase habitat fragmentation across landscapes by maintaining large, disturbed areas through trampling of cordgrass during targeted mussel consumption. Experiments and climate-disturbance recovery models show trampling alone slows marsh recovery by 3x while focused mussel predation creates marshes that may never recover from large-scale disturbances without hog eradication. Our work highlights that an invasive consumer can reshape ecosystems not just via competition and predation, but by disrupting key, positive species interactions that underlie resilience to climatic disturbances.
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- 2021
28. Coastal restoration success via emergent trait-mimicry is context dependent
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van der Heide, T., Temmink, R.J.M., Fivash, G.S., Bouma, T.J., Boström, C., Didderen, K., Esteban, N., Gaeckle, J., Gagnon, K., Infantes, E., van de Koppel, J., Lengkeek, W., Unsworth, R., Christianen, M.J.A., van der Heide, T., Temmink, R.J.M., Fivash, G.S., Bouma, T.J., Boström, C., Didderen, K., Esteban, N., Gaeckle, J., Gagnon, K., Infantes, E., van de Koppel, J., Lengkeek, W., Unsworth, R., and Christianen, M.J.A.
- Abstract
Coastal ecosystems provide vital ecosystem functions and services, but have been rapidly degrading due to human impacts . Restoration is increasingly considered key to reversing these losses, but is often unsuccessful. Recent work on seagrasses and salt marsh cordgrasses highlights that restoration yields can be greatly enhanced by temporarily mimicking key emergent traits. These traits are not expressed by individual seedlings or small clones, but emerge in clumped individuals or large clones to locally suppress environmental stress, causing establishment thresholds where such density-dependent self-facilitation is important for persistence. It remains unclear, however, to what extent the efficacy of restoration via emergent trait-based mimicry depends on the intensity of stressors. We test this in a restoration experiment with the temperate seagrass Zostera marina at four sites (Finla
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- 2021
29. A comparison of the “Reduced Losses” and “Increased Production” models for Mussel Bed Dynamics
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Sherratt, J.A., Liu, Q.-X., van de Koppel, J., Sherratt, J.A., Liu, Q.-X., and van de Koppel, J.
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Self-organised regular pattern formation is one of the foremost examples of the development of complexity in ecosystems. Despite the wide array of mechanistic models that have been proposed to understand pattern formation, there is limited general understanding of the feedback processes causing pattern formation in ecosystems, and how these affect ecosystem patterning and functioning. Here we propose a generalised model for pattern formation that integrates two types of within-patch feedback: amplification of growth and reduction of losses. Both of these mechanisms have been proposed as causing pattern formation in mussel beds in intertidal regions, where dense clusters of mussels form, separated by regions of bare sediment. We investigate how a relative change from one feedback to the other affects the stability of uniform steady states and the existence of spatial patterns. We conclude that there are important differences between the patterns generated by the two mechanisms, concerning both biomass distribution in the patterns and the resilience of the ecosystems to disturbances.
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- 2021
30. Bioengineering promotes habitat heterogeneity and biodiversity on mussel reefs
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van der Ouderaa, I.B.C., Claassen, J.R., van de Koppel, J., Bishop, M.J., Eriksson, B.K., van der Ouderaa, I.B.C., Claassen, J.R., van de Koppel, J., Bishop, M.J., and Eriksson, B.K.
- Abstract
Loss of biodiversity is among the most pressing global problems. Yet, despite its pertinent nature, the biological processes involved in the maintenance of biodiversity are poorly understood. Habitat heterogeneity is widely regarded as a key factor underpinning the biodiversity of land- and sea-scapes. However, it remains unclear how species coexist in many of those ecosystems that lack conspicuous heterogeneity. We demonstrate how spatially self-organized mussel reefs create microhabitats/heterogeneity that facilitate diverse invertebrate communities. By comparing seawater filled pools with open inlets in a mussel reef, we found that natural reef pools, emerging due to the habitat engineering of the mussels, strongly increased variation in organic enrichment and promoted beta-diversity compared to the surrounding tidal flat. These findings significantly extend the scale of influence typically described for self-organized habitats and highlight the importance of bioengineering and its positive effects on habitat heterogeneity and community diversity.
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- 2021
31. Evasion of tipping in complex systems through spatial pattern formation
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Rietkerk, M., Bastiaansen, R., Banerjee, S., van de Koppel, J., Baudena, M., Doelman, A., Rietkerk, M., Bastiaansen, R., Banerjee, S., van de Koppel, J., Baudena, M., and Doelman, A.
- Abstract
The concept of tipping points and critical transitions helps inform our understanding of the catastrophic effects that global change may have on ecosystems, Earth system components, and the whole Earth system. The search for early warning indicators is ongoing, and spatial self-organization has been interpreted as one such signal. Here, we review how spatial self-organization can aid complex systems to evade tipping points and can therefore be a signal of resilience instead. Evading tipping points through various pathways of spatial pattern formation may be relevant for many ecosystems and Earth system components that hitherto have been identified as tipping prone, including for the entire Earth system. We propose a systematic analysis that may reveal the broad range of conditions under which tipping is evaded and resilience emerges.
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- 2021
32. Density-dependent and species-specific sffects on self-organization modulate the resistance of mussel bed ecosystems to hydrodynamic stress
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Zardi, G.I., Nicastro, K.R., McQuaid, C.D., de Jager, M., van de Koppel, J., Seuront, L., Zardi, G.I., Nicastro, K.R., McQuaid, C.D., de Jager, M., van de Koppel, J., and Seuront, L.
- Abstract
Self-organized, regular spatial patterns emerging from local interactions among individuals enhance the ability of ecosystems to respond to environmental disturbances. Mussels self-organize to form large, regularly patterned biogenic structures that modify the biotic and abiotic environment and provide numerous ecosystem functions and services. We used two mussel species that form monospecific and mixed beds to investigate how species-specific behavior affects self-organization and resistance to wavestress. Perna perna has strong attachment but low motility, while Mytilus galloprovincialis shows the reverse. At low density, the less motile P. perna has limited spatial self-organization compared with M. galloprovincialis, while when coexisting, the two species formed random spatial patterns. At high density, the two species self-organized in similar ways, while when coexisting, patterns were less strong. Spatial pattern formations significantly shaped resistance to hydrodynamic stress. At low density, P. perna beds with strong attachment and M. galloprovincialis beds with strong spatial organization showed higher retention rates than mixed beds. At high density, the presence of strongly attached P. perna significantlyincreased retention in mixed and P. perna beds compared with M. galloprovincialis beds. Our study emphasizes the importance of the interplay of species-specific behaviors to spatial self-organization and stress tolerance in natural communities.
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- 2021
33. Reciprocal facilitation between annual plants and burrowing crabs: Implications for the restoration of degraded saltmarshes
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Qiu, D., Cui, B., Ma, X., Yan, J., Cai, Y., Xie, T., Gao, F., Wang, F., Sui, H., Bai, J., van de Koppel, J., Olff, H., Qiu, D., Cui, B., Ma, X., Yan, J., Cai, Y., Xie, T., Gao, F., Wang, F., Sui, H., Bai, J., van de Koppel, J., and Olff, H.
- Abstract
- Increasing evidence shows that facilitative interactions between species play an essential role in coastal wetland ecosystems. However, there is a lack of understanding of how such interactions can be used for restoration purposes in saltmarsh ecosystems. We therefore studied the mechanisms of reciprocal facilitative interactions between nativeannual plants, Suaeda salsa, and burrowing crabs, Helice tientsinensis, in a middle‐elevation saltmarsh (with generally high plant density and moderate tides) in the Yellow River Delta of China. We investigated the relationship between the densities of the plants and crab burrows in different seasons. Then, we tested whether and how saltmarsh plants and crabs indeed facilitate each other in a series of field and laboratory experiments. Finally, we applied the results by creating a field‐scale artificial approach for microtopographic modification to restore a degraded saltmarsh. We found that the density of plant seedlings in spring was positively correlated with the density of crab burrows in the previous autumn; moreover, the density of crab burrows was correlated with the density of plants in summer. The concave–convex surface microtopography created by crabs promoted seed retention and seedling establishment of saltmarsh plants in winter and spring. These plants in turn facilitated crabs by inhibiting predators, providing food and reducing physical stresses for crabs in summer and autumn. The experimental removal of saltmarsh plants decreased crab burrow density, while both transplanting and simulating plants in bare patches promoted crabs. The microtopographic modification, inspired by our new understanding of the interactions between saltmarsh plants and crabs, showed that these degraded saltmarsh ecosystems can be restored by a single ploughing intervention. Synthesis . Our results suggest a reciprocal facilitation between annual pla
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- 2021
34. Early warning signals for rate-induced critical transitions in salt marsh ecosystems
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Neijnens, F.K., Siteur, K., van de Koppel, J., Rietkerk, M., Neijnens, F.K., Siteur, K., van de Koppel, J., and Rietkerk, M.
- Abstract
Intertidal ecosystems are important because of their function as coastal protection and ecological value. Sea level rise may lead to submergence of salt marshes worldwide. Salt marshes can exhibit critical transitions if the rate of sea level rise exceeds salt marsh sedimentation, leading to a positive feedback between reduced sedimentation and vegetation loss, drowning the marshes. However, a general framework to recognize such rate-induced critical transitions and predict salt marsh collapse through early warning signals is lacking. Therefore, we apply the novel concept of rate-induced critical transitions to salt marsh ecosystems. We reveal rate-induced critical transitions and new geomorphic early warning signals for upcoming salt marsh collapse in a spatial model. These include a decrease in marsh height, the ratio of marsh area to creek area, and creek cliff steepness, as well as an increase in creek depth. Furthermore, this research predicts that increasing sediment capture ability by vegetation would be an effective measure to increase the critical rate of sea level rise at which salt marshes collapse. The generic spatial model also applies to other intertidal ecosystems with similar dynamics, such as tidal flats and mangroves. Our findings facilitate better resilience assessment of intertidal ecosystems globally and identifying measures to protect these ecosystems.
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- 2021
35. Sediment availability provokes a shift from Brownian to Lévy‐like clonal expansion in a dune building grass
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Reijers, V.C, Hoeks, S., van Belzen, J., Siteur, K., de Rond, A.J.A., van de Ven, C.N., Lammers, C., van de Koppel, J., van der Heide, T., Reijers, V.C, Hoeks, S., van Belzen, J., Siteur, K., de Rond, A.J.A., van de Ven, C.N., Lammers, C., van de Koppel, J., and van der Heide, T.
- Abstract
In biogeomorphic landscapes, plant traits can steer landscape development through plant-mediated feedback interactions. Interspecific differences in clonal expansion strategy can therefore lead to the emergence of different landscape organisations. Yet, whether landscape-forming plants adopt different clonal expansion strategies depending on their physical environment remains to be tested. Here, we use a field survey and a complementary mesocosm approach to investigate whether sediment deposition affects the clonal expansion strategy employed by dune-building marram grass individuals. Our results reveal a consistent shift in expansion pattern from more clumped, Brownian-like, movement in sediment-poor conditions, to patchier, Levy-like, movement under high sediment supply rates. Additional model simulations illustrate that the sediment-dependent shift in movement strategies induces a shift in optimisation of the cost-benefit relation between landscape engineering (i.e. dune formation) and expansion. Plasticity in expansion strategy may therefore allow landscape-forming plants to optimise their engineering ability depending on their physical landscape.
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- 2021
36. A convolution method to assess subgrid‐scale interactions between flow and patchy vegetation in biogeomorphic models
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Gourgue, O., van Belzen, J., Schwarz, C., Bouma, T.J., van de Koppel, J., Temmerman, S., Gourgue, O., van Belzen, J., Schwarz, C., Bouma, T.J., van de Koppel, J., and Temmerman, S.
- Abstract
Interactions between water flow and patchy vegetation are governing the functioning of many ecosystems. Yet, numerical models that simulate those interactions explicitly at the submeter patch scale to predict geomorphological and ecological consequences at the landscape scale (order of km2) are still very computationally demanding. Here, we present a novel and efficient convolution technique to incorporate biogeomorphic feedbacks in numerical models across multiple spatial scales (from less than 1 m2 to several km2). This new methodology allows for spatially refining coarse‐resolution hydrodynamic simulations of flow velocities (order of m) around fine‐resolution patchy vegetation patterns (order of 10 cm). Although flow perturbations around each vegetation grid cell are not simulated with the same level of accuracy as with more expensive finer‐resolution models, we show that our approach enables spatial refinement of coarse‐resolution hydrodynamic models by resolving efficiently subgrid‐scale flow velocity patterns within and around vegetation patches (mean error, spatial variability, and spatial correlation improved by, respectively, 13%, 66%, and 49% on average in our test cases). We also provide evidence that our approach can substantially improve the representation of important biogeomorphic processes, such as subgrid‐scale effects on net sedimentation rate and habitable surface area for vegetation (respectively 66% and 39% better on average). Finally, we estimate that replacing a fine‐resolution model by a coarser‐resolution model associated with the convolution method could reduce the computational time of real‐life fluctuating flow simulations by several orders of magnitude. This marks an important step forward toward more computationally efficient multiscale biogeomorphic modeling.
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- 2021
37. Salt marsh establishment in poorly consolidated muddy systems: effects of surface drainage, elevation, and plant age
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Cao, Haobing (author), Zhu, Zhenchang (author), van Belzen, Jim (author), Gourgue, Olivier (author), van de Koppel, J. (author), Temmerman, O. Stijn (author), Herman, P.M.J. (author), Zhang, Liquan (author), Yuan, Lin (author), Bouma, T. (author), Cao, Haobing (author), Zhu, Zhenchang (author), van Belzen, Jim (author), Gourgue, Olivier (author), van de Koppel, J. (author), Temmerman, O. Stijn (author), Herman, P.M.J. (author), Zhang, Liquan (author), Yuan, Lin (author), and Bouma, T. (author)
- Abstract
Conservation and restoration of salt marsh ecosystems are becoming increasingly important because of the many ecosystem services they provide. However, the processes controlling salt marsh establishment and persistence, especially on bare tidal flats in muddy areas, remain unclear. As muddy sediments typically experience a restriction of soil drainage, we expect that a surface drainage relief due to a heterogeneity topography, as might occur on the edge of tidal channels, can facilitate the establishment of salt marsh vegetation on muddy tidal flats. By means of a manipulative field experiment, using “Mega-Marsh Organ” mesocosms, we investigated the impact of surface drainage and elevation relative to mean sea level on (1) the survival of Spartina anglica seedlings from three different age classes: 1-yr, 3-month, and 1-week; and (2) the growth performance of mature S. anglica marsh tussocks. S. anglica seedling survival, especially in the establishment phase, was positively affected by better surface drainage, increases of seedling age, and higher elevation relative to mean sea level. That is, the survival rate of S. anglica seedlings at the end of 6th week increased from 0% (at surface water undrained, 1-week, 0 cm elevation) to 94.44% (at surface water drained, 1-yr, 90 cm elevation). In contrast, surface drainage did not affect the performance of large S. anglica marsh tussocks, as only increased elevation relative to mean sea level was shown to affect S. anglica tussock growth in terms of plant height, shoot numbers, and dry biomass. Based on our findings, we proposed a conceptual model to understand how surface drainage-driven feedbacks in a heterogeneous topography may be reinforced to induce salt marsh establishment in muddy systems. Further testing of present hypothesized model would be beneficial for insights into salt marsh establishment on tidal mudflats., Hydraulic Engineering
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- 2021
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38. Density-Dependent and Species-Specific Effects on Self-Organization Modulate the Resistance of Mussel Bed Ecosystems to Hydrodynamic Stress
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Zardi, G.I., Nicastro, K.R., McQuaid, C.D., de Jager, M., Van de Koppel, J., Seuront, L., Zardi, G.I., Nicastro, K.R., McQuaid, C.D., de Jager, M., Van de Koppel, J., and Seuront, L.
- Abstract
Self-organized, regular spatial patterns emerging from local interactions among individuals enhance the ability of ecosystems to respond to environmental disturbances. Mussels self-organize to form large, regularly patterned biogenic structures that modify the biotic and abiotic environment and provide numerous ecosystem functions and services. We used two mussel species that form monospecific and mixed beds to investigate how species-specific behavior affects self-organization and resistance to wave stress. Perna perna has strong attachment but low motility, while Mytilus galloprovincialis shows the reverse. At low density, the less motile P. perna has limited spatial self-organization compared with M. galloprovincialis, while when coexisting, the two species formed random spatial patterns. At high density, the two species self-organized in similar ways, while when coexisting, patterns were less strong. Spatial pattern formations significantly shaped resistance to hydrodynamic stress. At low density, P. perna beds with strong attachment and M. galloprovincialis beds with strong spatial organization showed higher retention rates than mixed beds. At high density, the presence of strongly attached P. perna significantly increased retention in mixed and P. perna beds compared with M. galloprovincialis beds. Our study emphasizes the importance of the interplay of species-specific behaviors to spatial self-organization and stress tolerance in natural communities.
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- 2021
39. Understanding scales of density-dependence to improve the use of resources in benthic mussel aquaculture
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Bertolini, C., Capelle, J. J., ter Veld, J. W.D., van de Koppel, J., Bouma, T. J., Proceskunde, Coastal dynamics, Fluvial systems and Global change, Proceskunde, Coastal dynamics, Fluvial systems and Global change, and Conservation Ecology Group
- Subjects
MECHANISM ,DYNAMICS ,Mytilus edulis ,Population ,Aquatic Science ,Biology ,Onderz. Form. D ,03 medical and health sciences ,Ecosystem ,education ,030304 developmental biology ,bottom culture ,0303 health sciences ,education.field_of_study ,Biomass (ecology) ,SEA ,04 agricultural and veterinary sciences ,Mussel ,Hydrodynamic ,Bottom-culture ,MYTILUS-EDULIS L ,Fishery ,Density dependence ,Productivity (ecology) ,Benthic zone ,Patches ,040102 fisheries ,Spatial ecology ,0401 agriculture, forestry, and fisheries ,Spatial patterning - Abstract
Shellfish aquaculture is considered a sustainable way to help meet rising protein demands worldwide. In shallow coastal dynamic ecosystems mussels can be cultivated directly on the seabed, however this method has a low return as mussels exposed to natural environments risk dislodgment, high predation rates, sedimentation and competition. The formation of spatial patterns in natural mussel beds, that result in 'organized patchiness', is thought to be an adaptive mechanism to reduce population losses. The driver and effects of this patterning need to be disentangled at multiple spatial scales in which patterns are observed. With a field experiment we aimed to understand how small-scale density (actual cover) and patterning (perimeter: area ratio of clumps and number of mussel layers) can be altered by manipulating large scale density (re-laying biomass), that farmers could control during seeding activity. Within this study we considered the interplay between environmental conditions (manipulating flow rate with the use of large mesh cages) and density for pattern development and persistence, and the repercussions of this on mussel productivity (growth and condition). We further investigated local scale processes, such as the role of within-clump biological activity (biodeposition), that may be a predictor for the larger scale observations of losses and persistence relative to density. We found that manipulating density by controlling seeding biomass from boats is not an accurate predictor of actual seabed density and resulting patterning. The growth and condition of the mussels was only influenced by local scale effects, resulting in high 'within clumps' variation. Aiming for an intermediate density to avoid both excessive fragmentation and excessive layering may be viewed as an optimal strategy to maximise returns, but we encourage the incorporation of the hierarchy of multiple scales of density in future studies of patterning that will allow the inclusion of these effects in a model of growth and productivity.
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- 2020
40. Vegetation causes channel erosion in a tidal landscape
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Temmerman, S., Bouma, T.J., Van de Koppel, J., Van der Wal, D., De Vries, M.B., and Herman, P.M.J.
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Tidal marshes -- Environmental aspects ,Beach erosion -- Causes of ,Biogeomorphology -- Research ,Plant communities -- Observations ,Earth sciences - Abstract
Vegetation is traditionally regarded to reduce the erosion of channels in both fluvial and tidal landscapes. We present a coupled hydrodynamic, morphodynamic, and plant growth model that simulates plant colonization and channel formation on an initially bare, flat substrate, and apply this model to a tidal landscape. The simulated landscape evolution is compared with aerial photos. Our results show that reduction of erosion by vegetation is only the local, on-site effect operating within static vegetation. Dynamic vegetation patches, which can expand or shrink, have a contrasting larger scale, off-site effect: they obstruct the flow, leading to flow concentration and channel erosion between laterally expanding vegetation patches. In contrast with traditional insights, our findings imply that in tidal landscapes, which are colonized by denser vegetation, channels are formed with a higher channel drainage density. Hence this study demonstrates that feedbacks between vegetation, flow, and landform have an important control on landscape evolution. Keywords: salt marsh, tidal creek, gully erosion, biogeomorphology.
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- 2007
41. Understanding scales of density-dependence to improve the use of resources in benthic mussel aquaculture
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Proceskunde, Coastal dynamics, Fluvial systems and Global change, Bertolini, C., Capelle, J. J., ter Veld, J. W.D., van de Koppel, J., Bouma, T. J., Proceskunde, Coastal dynamics, Fluvial systems and Global change, Bertolini, C., Capelle, J. J., ter Veld, J. W.D., van de Koppel, J., and Bouma, T. J.
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- 2020
42. Restoring mussel beds in highly dynamic environments by lowering environmental stressors
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Schotanus, J., Capelle, J.J., Parée, E., Fivash, G.S., Van de Koppel, J., Bouma, T.J., Schotanus, J., Capelle, J.J., Parée, E., Fivash, G.S., Van de Koppel, J., and Bouma, T.J.
- Abstract
Restoration of coastal ecosystem engineers that trap sediment and dampen waves has proven to be difficult, especially in the wave‐exposed and eroding areas where they are needed the most. Environmental stressors, such as hydrodynamic stress and predation, can only be overcome if transplanted organisms are able to establish self‐facilitating feedbacks. We investigate if the artificial lowering of multiple environmental stressors can be used to give transplanted juveniles the opportunity to form a self‐sustainable system and thereby increase their long‐term survival on wave‐exposed and eroding shores. We designed a large field experiment using juvenile mussels (Mytilus edulis) as model species on a wave‐exposed tidal flat in the Oosterschelde estuary (the Netherlands). We tested if the environmental stress caused by a high predation pressure and wave‐driven dislodgement could be reduced by a combination of artificial structures such as fences (to exclude predatory crabs), attachment substrates (such as coir‐net or oyster shells), and breakwaters. Despite a low overall mussel survival (29%), we found that under strong hydrodynamic conditions, experimental fences and attachment substrates increased the retention of transplanted mussel seed. However, modification of local hydrodynamic conditions using breakwaters did not improve mussel coverage preservation. Overall, this study highlights the potential of using techniques that lower multiple environmental stressors to create a window of opportunity for establishment in highly dynamic ecosystems.
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- 2020
43. Promoting self‐facilitating feedback processes in coastal ecosystem engineers to increase restoration success: Testing engineering measures
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Schotanus, J., Walles, B., Capelle, J.J., van Belzen, J., van de Koppel, J., Bouma, T.J., Schotanus, J., Walles, B., Capelle, J.J., van Belzen, J., van de Koppel, J., and Bouma, T.J.
- Abstract
1. Coastal ecosystem engineers often depend on self‐facilitating feedbacks to ameliorate environmental stress. This makes the restoration of such coastal ecosystem engineers difficult. We question if we can increase transplantation success in highly dynamic coastal areas by engineering measures that promote the development of self‐facilitating feedback processes.2. Intertidal blue mussels Mytilus edulis are a typical example of ecosystem engineers that are difficult to restore. A lack of self‐facilitating feedbacks at low densities limits establishment success when young mussels are transplanted on dynamic mudflats.3. In a large field experiment, we investigated the possibility of increasing transplantation success by stimulating the formation of an aggregated spatial configuration in mussels, thereby reducing hydrologically induced dislodgment and the risks of predation. For this, we applied engineering measures in the form of fences that trapped wave dislodged mussels.4. Mussel loss rates were significantly lower when mussels were placed between both artificial fences, and in high densities (4.2 kg/m2) compared with mussels placed in areas without fences and in low densities (2.1 kg/m2). The fences induced the formation of a banded pattern with high local mussel densities, which locally reduced predation.5. Synthesis and applications. Our results underline the importance of actively promoting the development of self‐facilitating processes, such as aggregation into patterns, in restoration projects of ecosystem engineers. In particular, the current study shows that engineering measures can help to initiate these kinds of self‐facilitating interactions, especially in highly dynamic areas.
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- 2020
44. A healthy trophic structure underlies the resistance of pristine seagrass beds to nutrient enrichment
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Yan, J., van der Heide, T., Cui, B., Bai, J., Ysebaert, T., van de Koppel, J., Yan, J., van der Heide, T., Cui, B., Bai, J., Ysebaert, T., and van de Koppel, J.
- Abstract
Whether pristine ecosystems with intact trophic structures are more resilient to anthropogenic pressures than ecosystems facing human exploitation is a pressing question to ecological theory and management. For coastal vegetated ecosystems such as kelp forests and seagrass meadows, a number of studies recently highlighted that under eutrophic conditions, trophic cascades are particularly important in buffering or reducing negative effects of nutrient enrichment. Yet, it currently remains unclear how nutrient enrichment and trophic downgrading interact in oligotrophic coastal ecosystems with an intact trophic structure. Here, we factorially manipulated nutrient loading and the interactions within a tri‐trophic food chain within a pristine, oligotrophic seagrass ecosystem to investigate how trophic downgrading affects its ability to buffer against eutrophication. Results revealed that nutrient addition stimulates seagrass production, while reducing the growth of benthic microalgae, presumably because the thicker seagrass canopy reduced light availability. Trophic downgrading by excluding predators, however, almost completely negated these nutrient effects, as the release of herbivores from predation strongly enhanced grazing pressure on seagrass. Exclusion of grazers in turn restored seagrass biomass by allowing the nutrient addition treatment to regain its effect, confirming that a tri‐trophic cascade mediated how enhanced nutrient loading affected our system. Our results highlight that a healthy trophic structure is vital for the ability of pristine coastal ecosystems to buffer eutrophication, as trophic downgrading may degrade their ability to absorb enhanced nutrient loading. Hence, our findings emphasize the potential for multiple anthropogenic impacts to interact synergistically in degrading natural ecosystems.
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- 2020
45. Spatial self-organization as a new perspective on cold-water coral mound development
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van der Kaaden, A.-S., van Oevelen, D., Rietkerk, M., Soetaert, K., van de Koppel, J., van der Kaaden, A.-S., van Oevelen, D., Rietkerk, M., Soetaert, K., and van de Koppel, J.
- Abstract
Cold-water corals build extensive reefs on the seafloor that are oases of biodiversity, biomass, and organic matter processing rates. The reefs baffle sediments, and when coral growth and sedimentation outweigh ambient sedimentation, carbonate mounds of tens to hundreds of meters high and several kilometers wide can form. Because coral mounds form over ten-thousands of years, their development process remains elusive. While several environmental factors influence mound development, the mounds also have a major impact on their environment. This feedback between environment and mounds, and how this drives mound development is the focus of this paper. Based on the similarity of spatial coral mound patterns and patterns in self-organized ecosystems, we provide a new perspective on coral mound development. In accordance with the theory of self-organization through scale-dependent feedbacks, we first elicit the processes that are known to affect mound development, and might cause scale-dependent feedbacks. Then we demonstrate this concept with model output from a study on the Logachev area, SW Rockall Trough margin. Spatial patterns in mound provinces are the result of a complex set of interacting processes. Spatial self-organization provides a framework in which to place and compare these processes, so as to assess if and how they contribute to pattern formation in coral mounds.
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- 2020
46. Self-organization of river vegetation leads to emergent buffering of river flows and water levels
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Cornacchia, L., Wharton, G., Davies, G., Grabowski, R.C., Temmerman, S., van der Wal, D., Bouma, T.J., van de Koppel, J., Cornacchia, L., Wharton, G., Davies, G., Grabowski, R.C., Temmerman, S., van der Wal, D., Bouma, T.J., and van de Koppel, J.
- Abstract
Global climate change is expected to impact hydrodynamic conditions in stream ecosystems. There is limited understanding of how stream ecosystems interact and possibly adapt to novel hydrodynamic conditions. Combining mathematical modelling with field data, we demonstrate that bio-physical feedback between plant growth and flow redistribution triggers spatial self-organization of in-channel vegetation that buffers for changed hydrological conditions. The interplay of vegetation growth and hydrodynamics results in a spatial separation of the stream into densely vegetated, low-flow zones divided by unvegetated channels of higher flow velocities. This self-organization process decouples both local flow velocities and water levels from the forcing effect of changing stream discharge. Field data from two lowland, baseflow-dominated streams support model predictions and highlight two important stream-level emergent properties: vegetation controls flow conveyance in fast-flowing channels throughout the annual growth cycle, and this buffering of discharge variations maintains water depths and wetted habitat for the stream community. Our results provide important evidence of how plant-driven self-organization allows stream ecosystems to adapt to changing hydrological conditions, maintaining suitable hydrodynamic conditions to support high biodiversity.
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- 2020
47. Historic storms and the hidden value of coastal wetlands for nature-based flood defence
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Zhu, Z., Vuik, V., Visser, P.J., Soens, T., van Wesenbeeck, B.K., van de Koppel, J., Jonkman, S.N., Temmerman, S., Bouma, T.J., Zhu, Z., Vuik, V., Visser, P.J., Soens, T., van Wesenbeeck, B.K., van de Koppel, J., Jonkman, S.N., Temmerman, S., and Bouma, T.J.
- Abstract
Global change amplifies coastal flood risks and motivates a paradigm shift towards nature-based coastal defence, where engineered structures are supplemented with coastal wetlands such as saltmarshes. Although experiments and models indicate that such natural defences can attenuate storm waves, there is still limited field evidence on how much they add safety to engineered structures during severe storms. Using well-documented historic data from the 1717 and 1953 flood disasters in Northwest Europe, we show that saltmarshes can reduce both the chance and impact of the breaching of engineered defences. Historic lessons also reveal a key but unrecognized natural flood defence mechanism: saltmarshes lower flood magnitude by confining breach size when engineered defences have failed, which is shown to be highly effective even with long-term sea level rise. These findings provide new insights into the mechanisms and benefits of nature-based mitigation of flood hazards, and should stimulate the development of novel safety designs that smartly harness different natural coastal defence functions.
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- 2020
48. Facilitating foundation species: The potential for plant–bivalve interactions to improve habitat restoration success
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Gagnon, K., Rinde, E., Bengil, E.G.T., Carugati, L., Christianen, M.J.A., Danovaro, R., Gambi, C., Govers, L.L., Kipson, S., Meysick, L., Pajusalu, L., Tüney Kizilkaya, I., van de Koppel, J., van der Heide, T., van Katwijk, M.M., Boström, C., Gagnon, K., Rinde, E., Bengil, E.G.T., Carugati, L., Christianen, M.J.A., Danovaro, R., Gambi, C., Govers, L.L., Kipson, S., Meysick, L., Pajusalu, L., Tüney Kizilkaya, I., van de Koppel, J., van der Heide, T., van Katwijk, M.M., and Boström, C.
- Abstract
1. Vegetated marine and freshwater habitats are being increasingly lost around the world. Habitat restoration is a critical step for conserving these valuable habitats, but new approaches are needed to increase restoration success and ensure their survival.2. We investigated interactions between plants and bivalves through a review and analysis of 491 studies, determined the effects, mechanisms and key environmental variables involved in and driving positive and negative interactions, and produced guidelines for integrating positive interactions into restoration efforts in different habitats.3. Fifty per cent of all interactions (both correlative and experimental studies) were positive. These were predominant between epifaunal bivalves and plants in all habitats, and between infaunal bivalves and plants in subtidal habitats. Plants primarily promoted bivalve survival and abundance by providing substrate and shelter, while bivalves promoted plant growth and survival by stabilizing and fertilizing the sediment, and reducing water turbidity. The prevalence of positive interactions increased with water temperature in subtidal habitats, but decreased with water temperature in intertidal habitats. The subset of studies conducted in a restoration context also showed mostly positive interactions.4. Twenty‐five per cent of all interactions were negative, and these were predominant between plants and infaunal bivalves in intertidal habitats, except sulphide‐metabolizing bivalves, which facilitated plant survival. Interactions involving non‐native species were also mostly negative.5. Synthesis and applications. Promoting facilitative interactions through plant–bivalve co‐restoration can increase restoration success. The prevalence of positive interactions depends on habitat and environmental conditions such as temperature, and was especially important in subtidal habitats (involving both infaunal and epifaunal bivalves) and in intertidal habitats (involving only epifaunal biva
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- 2020
49. Estuarine biofilm patterns: modern analogues for Precambrian self‐organization
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van de Vijsel, R.C., van Belzen, J., Bouma, T.J., van der Wal, D., Cusseddu, V., Purkis, S.J., Rietkerk, M., van de Koppel, J., van de Vijsel, R.C., van Belzen, J., Bouma, T.J., van der Wal, D., Cusseddu, V., Purkis, S.J., Rietkerk, M., and van de Koppel, J.
- Abstract
This field and laboratory study examines whether regularly patterned biofilms on present‐day intertidal flats are equivalent to microbially induced bedforms found in geological records dating back to the onset of life on Earth. Algal mats of filamentous Vaucheria species, functionally similar to microbial biofilms, cover the topographic highs of regularly spaced ridge–runnel bedforms. As regular patterning is typically associated with self‐organization processes, indicators of self‐organization are tested and found to support this hypothesis. The measurements suggest that biofilm‐induced sediment trapping and biostabilization enhance bedform relief, strength and multi‐year persistence. This demonstrates the importance of primitive organisms for sedimentary landscape development. Algal‐covered ridges consist of wavy‐crinkly laminated sedimentary deposits that resemble the layered structure of fossil stromatolites and microbially induced sedimentary structures. In addition to layering, both the morphological pattern and the suggested formation mechanism of the recent bedforms are strikingly similar to microbialite strata found in rock records from the Precambrian onwards. This implies that self‐organization was an important morphological process in times when biofilms were the predominant sessile ecosystem. These findings furthermore emphasize that self‐organization dynamics, such as critical transitions invoking ecosystem emergence or collapse, might have been captured in fossil microbialites, influencing their laminae. This notion may be important for paleoenvironmental reconstructions based on such strata.
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- 2020
50. Vegetation recovery on neighboring tidal flats forms an Achilles' heel of saltmarsh resilience to sea level rise
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Zhu, Z., van Belzen, J., Zhu, Q., van de Koppel, J., Bouma, T.J., Zhu, Z., van Belzen, J., Zhu, Q., van de Koppel, J., and Bouma, T.J.
- Abstract
Coastal wetlands such as saltmarshes are valued as prominent buffering ecosystems to global climate change and sea level rise (SLR), yet their long‐term persistence may also be threatened by these global change stressors. While saltmarshes are increasingly thought to be resilient to SLR owing to high vertical marsh adaptability, their long‐term stability remains uncertain due to our poor understanding of marsh resilience at the marsh‐tidal flat interface, where wave disturbance can progressively shift vegetated marsh toward a bare tidal flat state. Here, we explore how SLR affects vegetation recoverability on tidal flats using cordgrass, a globally common saltmarsh foundation species, as a model plant. Combined field and model results demonstrate that small increases in wave forcing due to raised water depth over tidal flats can dramatically weaken or even block vegetation recovery from eroding marsh edges, through hampering seed persistence. Vegetation recovery on tidal flats next to the marsh edge thus represents an unrecognized Achilles' heel of marsh resilience to SLR, which if ignored may cause underestimation of marsh vulnerability. These findings are highly relevant for a more comprehensive assessment of marsh susceptibility to SLR in systems where seeds play an essential role in revegetation of tidal flats, and highlight the importance of maintaining either a wave‐protected or well‐elevated tidal flat near the marsh edge that allows for quick vegetation recovery for supporting resilient marshes.
- Published
- 2020
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