Your search keyword '"Gregory S. Fivash"' showing total 13 results

1. Early indicators of tidal ecosystem shifts in estuaries

Author

Gregory S. Fivash, Stijn Temmerman, Maarten G. Kleinhans, Maike Heuner, Tjisse van der Heide, and Tjeerd J. Bouma

Subjects

Science

Abstract

Transitions from bare tidal flats to vegetated marshes are an example of shift between alternative stable ecosystem states. Here, the authors use remote sensing and modelling to quantify three stages in tidal flat evolution and identify early warning signals.

Published

2023

2. Morphodynamic signatures derived from daily surface elevation dynamics can explain the morphodynamic development of tidal flats

Author

Tim J. Grandjean, Jaco C. de Smit, Jim van Belzen, Gregory S. Fivash, Jeroen van Dalen, Tom Ysebaert, and Tjeerd J. Bouma

Subjects

Surface elevation dynamics, Tidal flat trajectories, Morphodynamic development, Morphodynamic signature, Bed level dynamics, River, lake, and water-supply engineering (General), TC401-506

Abstract

Understanding the sensitivity of tidal flats to environmental changes is challenging. Currently, most studies rely on process-based models to systematically explain the morphodynamic evolution of tidal flats. In this study, we proposed an alternative empirical approach to explore tidal flat dynamics using statistical indices based on long-term time series of daily surface elevation development. Surface elevation dynamic (SED) indices focus on the magnitude and period of surface elevation changes, while morphodynamic signature (MDS) indices relate sediment dynamics to environmental drivers. The statistical analyses were applied to an intervention site in the Netherlands to determine the effect of recently constructed groynes on the tidal flat. Using these analyses, we were able to (1) detect a reduction in the daily SED and (2) determine that the changes in the daily SED were predominantly caused by the reduction in wave impact between the groynes rather than the reduction in tidal currents. Overall, the presented results showed that the combination of novel statistical indices provides new insights into the trajectories of tidal flats, ecosystem functioning, and sensitivity to physical drivers (wind and tides). Finally, we suggested how the SED and MDS indices may help to explore the future trajectories and climate resilience of intertidal habitats.

Published

2023

3. Mimicry of emergent traits amplifies coastal restoration success

Author

Ralph J. M. Temmink, Marjolijn J. A. Christianen, Gregory S. Fivash, Christine Angelini, Christoffer Boström, Karin Didderen, Sabine M. Engel, Nicole Esteban, Jeffrey L. Gaeckle, Karine Gagnon, Laura L. Govers, Eduardo Infantes, Marieke M. van Katwijk, Silvija Kipson, Leon P. M. Lamers, Wouter Lengkeek, Brian R. Silliman, Brigitta I. van Tussenbroek, Richard K. F. Unsworth, Siti Maryam Yaakub, Tjeerd J. Bouma, and Tjisse van der Heide

Subjects

Science

Abstract

Coastal restoration tends to be failure-prone and expensive. Temmink and colleagues improve seagrass and cordgrass transplant survival in field experiments using biodegradable structures which temporarily mimic self-facilitation occurring in mature vegetation stands, and combine onsite and laboratory measurements on sediment stability and stem movement to test the biophysical mechanisms.

Published

2020

4. In-Culture Selection and the Potential Effects of Changing Sex Ratios on the Reproductive Success of Multiannual Delayed Gametophytes of Saccharina latissima and Alaria esculenta

Author

Alexander P. J. Ebbing, Gregory S. Fivash, Nuria B. Martin, Ronald Pierik, Tjeerd J. Bouma, Jacco C. Kromkamp, and Klaas Timmermans

Subjects

delayed gametophytes, reproduction, gametophyte density, sporophytes, kelp aquaculture, life cycle controls, Naval architecture. Shipbuilding. Marine engineering, VM1-989, Oceanography, GC1-1581

Abstract

Multiannual delayed gametophyte cultures can stay vegetative for years, while also having the ability to grow. This study aims to investigate whether male and female multiannual delayed gametophyte strains of the species Saccharina latissima and Alaria esculenta grow at different rates in culture. We furthermore assessed how changing sex ratios can affect the reproductive yields of these cultures. The results indicate that the reproductive yield of cultures declines with decreasing male:female ratios, a correlation that becomes especially apparent at higher culture densities for both species. Female gametophyte densities in particular affected the observed reproductive yield of the cultures, with S. latissima cultures showing a clear reproductive optimum (sporophytes·mL−1) at 0.013 mg·mL−1 DW female gametophyte biomass, while the reproductive success of A. esculenta peaked at a density of 0.025 mg·mL−1 DW of female gametophyte biomass, after which the reproductive yield started to decline in both species. The results show that the sex ratio of a gametophyte culture is an important biotic life cycle control, with higher amounts of female gametophyte biomass halting gametophyte reproduction. Understanding how these changing sex ratios in gametophyte cultures affect reproduction is especially important in the aquaculture of kelp, where reliable preforming cultures are key to long-term success.

Published

2021

5. Can cheniers protect mangroves along eroding coastlines? – The effect of contrasting foreshore types on mangrove stability

Author

Celine E.J. van Bijsterveldt, Daphne van der Wal, Alejandra Gijón Mancheño, Gregory S. Fivash, Muhammad Helmi, Tjeerd J. Bouma, Department of Water Resources, Digital Society Institute, UT-I-ITC-WCC, and Faculty of Geo-Information Science and Earth Observation

Subjects

ITC-HYBRID, Environmental Engineering, Cheniers, Wave reduction, ITC-ISI-JOURNAL-ARTICLE, Foreshore, Mangrove dynamics, Management, Monitoring, Policy and Law, Mudflats, Nature and Landscape Conservation

Abstract

Mangrove forests are increasingly valued as wave-attenuating buffers in coastal flood defence strategies. However, as mangroves are vulnerable to wave-induced erosion, this raises the question, how can the stability of these protective mangrove forests be promoted? To address this question, we investigate how mangrove dynamics in a microtidal system can be related to different types of foreshores. We used remote sensing to investigate mangrove fringe stability over multiple years in relation to intertidal mudflat width (i.e., emerged at low tide) and the presence stability of cheniers, which are sand bodies on top of muddy foreshores that are characteristic for eroding coastlines. In addition, we investigated local and short-term foreshore effects by measuring wave propagation across two cross-shore transects, one with a mudflat and chenier and one with a deeper tidal flat foreshore. The satellite images (Sentinel-2) revealed that mangrove dynamics over multiple years and seasons were related to chenier presence and stability. Without a chenier, a mudflat width of 110 m (95%CI: 76–183 m) was required to make mangrove expansion more likely than mangrove retreat. When a stable chenier was present offshore for two years or more, a mudflat width of only 16 m (95%CI: 0–43 m) was enough to flip chances in favor of mangrove expansion. However, mangrove expansion remained heavily influenced by seasonal changes, and was highly event driven, succeeding only once in several years. Finally, although mudflat width was a direct driver of mangrove expansion, and could be targeted as such in coastal management, our field measurements demonstrated that cheniers also have an indirect effect on mangrove expansion. These sand banks significantly reduce wave height offshore, thereby likely creating favorable conditions for mudflat accretion landward, and thus mangrove habitat expansion. This makes stabilization - and possibly also the temporary creation - of cheniers an interesting target for mangrove conservation and restoration.

Published

2023

6. Temporal dynamics of heatwaves are key drivers of sediment mixing by bioturbators

Author

Zhengquan Zhou, Natalie Steiner, Gregory S. Fivash, Francesco Cozzoli, Daniel B. Blok, Lennart van IJzerloo, Jeroen van Dalen, Tom Ysebaert, Brenda Walles, and Tjeerd J. Bouma

Subjects

Onderz. Form. D, Life Science, Aquatic Science, Oceanography

Abstract

Heatwaves affect tidal flat ecosystems by altering the bioturbating behavior of benthic species, with potential consequences for sediment oxygenation, particle mixing, and erodibility. Although the frequency and duration of heatwaves are expected to increase under global warming scenarios, we lack insights into how heatwaves' temporal dynamics affect bioturbating behaviors. Using the widely distributed bioturbator Cerastoderma edule as model species, we quantified how heatwaves with identical heat-sum but different temporal dynamics (i.e., 3- vs. 6-d heating and normal temperature cycles) affect bioturbating behaviors and the sediment mixing processes in tidal mesocosms. Our results show that short but frequent 3-d heatwave cycles increased the magnitude of bioturbating behaviors, thereby resulting in more bio-mixed sediment than observed under infrequent prolonged 6-d heatwave cycles. This unexpected result could be ascribed to the weakening health condition indicated by a high death rate (47.37%) under 6-d heatwave cycles than in 3-d and no-heatwave control cycles. Present findings reveal that the impact of heatwaves on sediment bioturbation will strongly depend on the temporal dynamics of future heatwaves: bioturbation will be enhanced unless the heatwave duration exceeds species resistance and increases mortality.

Published

2023

7. Biodegradable artificial reefs enhance food web complexity and biodiversity in an intertidal soft‐sediment ecosystem

Author

Janne Nauta, Marjolijn J. A. Christianen, Ralph J. M. Temmink, Gregory S. Fivash, Beatriz Marin‐Diaz, Valérie C. Reijers, Karin Didderen, Emma Penning, Annieke C. W. Borst, Jannes H. T. Heusinkveld, Maarten Zwarts, Peter M. J. M. Cruijsen, Nadia Hijner, Wouter Lengkeek, Leon P. M. Lamers, Tjisse van der Heide, Tjeerd J. Bouma, Daphne van der Wal, Han Olff, Laura L. Govers, Department of Water Resources, Digital Society Institute, UT-I-ITC-WCC, Faculty of Geo-Information Science and Earth Observation, Spatial Ecology and Global Change, Proceskunde, and ESL General Section

Subjects

Aquatic Ecology and Water Quality Management, self-facilitation, WIMEK, Ecology, mussel, Aquatic Ecology, Aquatische Ecologie en Waterkwaliteitsbeheer, coastal restoration, foundation species, ITC-HYBRID, biogenic reefs, ITC-ISI-JOURNAL-ARTICLE, food web complexity, ecological networks, artificial reefs

Abstract

Reef-forming species form integral aspects of coastal ecosystems, but are rapidly degrading world-wide. To mitigate these declines, nature managers increasingly rely on the restoration of habitat-structuring, reef-forming species by, for example, introducing artificial reefs that may directly function as complex reef habitat. Since the use of biodegradable structures to restore biogenic reefs is becoming a popular technique, its effectiveness as reef habitat must be assessed. Therefore, we examine the trophic complexity on experimental large-scale biodegradable artificial reefs using food web network analysis. We placed biodegradable artificial reefs on soft-sediment intertidal flats in the Dutch Wadden Sea in a large-scale (~650 m) and 2.5-year-long experiment. We compared food web networks and biodiversity indicators between biodegradable reefs and bare controls and quantified species composition inside and near the artificial reef community to assess the expansion of the reef community. During 2.5 years, we observed that artificial reefs changed food web networks compared to bare controls: in species richness (+76%), link density (the number of interactions per species; +15%) and the fraction of basal species (species of lowest trophic level; +40%), but lowered the connectance: the realized fraction of all possible links between species (−33%). Their effects on food web networks increased over time with a higher species richness (+22%) and more complex food web (link density +13%) on the artificial reef 2.5 years after deployment compared to 1.5 years. However, the effects of the reefs did not extend beyond the reef structures; the species composition and biodiversity of macrozoobenthos near the reefs were comparable to the control. Synthesis and applications. This study shows that biodegradable artificial reefs offer an effective tool for the restoration of food web complexity and biodiversity of intertidal soft-sediment systems. However, application needs to be carefully considered as the reef-building species did not expand beyond our structures, despite the ambitious spatial extent of this experiment. Therefore, we recommend restoration practitioners to design artificial reefs in such a way that they generate ecosystem connectivity (facilitation of higher trophic levels) and biogeomorphological effects on a landscape scale (reef expansion beyond the structures).

Published

2023

8. Growth forms and life-history strategies predict the occurrence of aquatic macrophytes in relation to environmental factors in a shallow peat lake complex

Author

Ralph J.M. Temmink, Wouter Lengkeek, Tjisse van der Heide, Karin Didderen, Winnie Rip, Tjeerd J. Bouma, Leon P. M. Lamers, Alfons J. P. Smolders, Gregory S. Fivash, Martijn Dorenbosch, Conservation Ecology Group, Van der Heide group, and Proceskunde

Subjects

Vegetation, Peat, Ecology, Aquatic ecosystem, Aquatic Ecology, Fetch, Nutrients, Aquatic Science, Macrophyte, Life history theory, Nutrient, Habitat, Submerged macrophytes, Aquatic plant, Environmental science, Floating-leaved rooted macrophytes, Overwintering, Water depth

Abstract

Aquatic ecosystems provide vital services, and macrophytes play a critical role in their functioning. Conceptual models indicate that in shallow lakes, plants with different growth strategies are expected to inhabit contrasting habitats. For shallow peat lakes, characterized by incohesive sediments, roles of growth forms, life-history strategies and environmental factors in determining the occurrence of aquatic vegetation remain unknown. In a field survey, we sampled 64 points in a peat lake complex and related macrophyte occurrence to growth forms (floating-leaved rooted and submerged), life-history strategies for overwintering (turions, seeds, rhizomes) and environmental factors (water depth, fetch, and porewater nutrients). Our survey showed that macrophyte occurrence relates to water depth, wind-fetch, and nutrients, and depends on growth form and life-history strategies. Specifically, rooted floating-leaved macrophytes occur at lower wind-fetch/shallower waters. Submerged macrophytes occur from low to greater wind-fetch/water depth, depending on life-history strategies; macrophytes with rhizomes occur at greater wind-fetch/depth relative to species that overwinter with seeds or turions. We conclude that growth form and life-history strategies for overwintering predict macrophytes occurrence regarding environmental factors in peat lakes. Therefore, we propose an adapted model for macrophyte occurrence for such lakes. Altogether, these results may aid in species-selection to revegetate peat lakes depending on its environment.

Published

2021

9. Restoration of biogeomorphic systems by creating windows of opportunity to support natural establishment processes

Author

Jeroen van Dalen, Tjisse van der Heide, Francesco Ballio, Ralph J.M. Temmink, Manuel D’Angelo, Gregory S. Fivash, Karin Didderen, Wouter Lengkeek, Tjeerd J. Bouma, Van der Heide group, Conservation Ecology Group, and Proceskunde

Subjects

0106 biological sciences, restoration, microtopography, Growing season, 010603 evolutionary biology, 01 natural sciences, Article, Natural (archaeology), Environment variable, salt marshes, Humans, Ecosystem, windows of opportunity, geography, geography.geographical_feature_category, Ecology, 010604 marine biology & hydrobiology, Aquatic Ecology, Sediment, Articles, Vegetation, Flume, natural establishment, Seedlings, Salt marsh, Wetlands, Seeds, Environmental science, biogeomorphic systems

Abstract

In degraded landscapes, recolonization by pioneer vegetation is often halted by the presence of persistent environmental stress. When natural expansion does occur, it is commonly due to the momentary alleviation of a key environmental variable previously limiting new growth. Thus, studying the circumstances in which expansion occurs can inspire new restoration techniques, wherein vegetation establishment is provoked by emulating natural events through artificial means. Using the salt‐marsh pioneer zone on tidal flats as a biogeomorphic model system, we explore how locally raised sediment bed forms, which are the result of natural (bio)geomorphic processes, enhance seedling establishment in an observational study. We then conduct a manipulative experiment designed to emulate these facilitative conditions in order to enable establishment on an uncolonized tidal flat. Here, we attempt to generate raised growth‐promoting sediment bed forms using porous artificial structures. Flume experiments demonstrate how these structures produce a sheltered hydrodynamic environment in which suspended sediment and seeds preferentially settle. The application of these structures in the field led to the formation of stable, raised sediment platforms and the spontaneous recruitment of salt‐marsh pioneers in the following growing season. These recruits were composed primarily of the annual pioneering Salicornia genus, with densities of up to 140 individuals/m2 within the structures, a 60‐fold increase over ambient densities. Lower abundances of five other perennial species were found within structures that did not appear elsewhere in the pioneer zone. Furthermore, recruits grew to be on average three times greater in mass inside of the structures than in the neighboring ambient environment. The success of this restoration design may be attributed to the combination of three factors: (1) enhanced seed retention, (2) suppressed mortality, and (3) accelerated growth rates on the elevated surfaces generated by the artificial structures. We argue that restoration approaches similar to the one shown here, wherein the conditions for natural establishment are actively mimicked to promote vegetation development, may serve as promising tools in many biogeomorphic ecosystems, ranging from coastal to arid ecosystems.

Published

2021

10. Initiating and upscaling mussel reef establishment with life cycle informed restoration: Successes and future challenges

Author

Han Olff, Janne Nauta, Wouter Lengkeek, Karin Didderen, P. M. J. M. Cruijsen, Gregory S. Fivash, Tjisse van der Heide, Tjeerd J. Bouma, Jannes H. T. Heusinkveld, Leon P. M. Lamers, Valérie C. Reijers, Laura L. Govers, Marjolijn J. A. Christianen, Ralph J.M. Temmink, Emma Penning, Beatriz Marin-Diaz, Van der Heide group, Govers group, Olff group, Piersma group, Conservation Ecology Group, Spatial Ecology and Global Change, Sub Subatomic Physics (SAP), Proceskunde, and Coastal dynamics, Fluvial systems and Global change

Subjects

Aquatic Ecology and Water Quality Management, Environmental Engineering, Monitoring, Mytilus edulis, Intertidal zone, Management, Monitoring, Policy and Law, Natural (archaeology), Predation, Establishment, Ecosystem, Mussel beds, Reef, Blue mussel, Nature and Landscape Conservation, Biomass (ecology), geography, WIMEK, geography.geographical_feature_category, Policy and Law, Aquatic Ecology, Mussel, Aquatische Ecologie en Waterkwaliteitsbeheer, Management, BESE, Fishery, Environmental science, Facilitation, Substrate

Abstract

Worldwide, coastal ecosystems are rapidly degrading in quality and extent. While novel restoration designs include facilitation to enhance restoration success in stressful environments, they typically focus on a single life-stage, even though many organisms go through multiple life-stages accompanied by different bottlenecks. A new approach – life cycle informed restoration – was designed to ameliorate multiple bottlenecks throughout an organism's life cycle. It has successfully been tested on a small scale to facilitate intertidal bivalve reef formation in the Netherlands and Florida. Yet, it remains unknown whether this approach can be scaled to ecosystem-relevant scales. To test whether life cycle informed restoration is upscalable, we conducted a large-scale restoration experiment using blue mussel reefs as a model system. In our experiment, we used biodegradable structures to temporarily facilitate mussel reef formation by providing early-life settlement substrates, and subsequently, reduce post-settlement predation on an intertidal flat in the Wadden Sea, the Netherlands. The structures were placed in 10 × 20 m plots, mimicking bands found in natural mussel beds, spread out across 650 m, and were followed for two years. Ourresults show that the structures enhance mussel biomass (0.7 ± 0.2 kg DW m −2), as mussels were absent in bare plots. However, biomass varied within plots; in intact structures it was 60 times higher (1.2 ± 0.2 kg DW m−2) than in those that became buried (0.02 ± 0.009 kg DW m−2). Next to burial, 18–46% of the structures were lost due to technical failure, especially during winters at this exposed site. We show that the life cycle informed restoration principle works, but we encountered technical challenges due to larger scale processes (e.g. sedimentation). Furthermore, environmental information is essential for site selection, and for restoration, the functioning of such structures should be tested under extreme conditions before upscaling.

Published

2022

11. Overcoming establishment thresholds for peat mosses in human‐made bog pools

Author

Tjeerd J. Bouma, P. M. J. M. Cruijsen, Tjisse van der Heide, Gregory S. Fivash, Wouter Lengkeek, Leon P. M. Lamers, Karin Didderen, Ralph J.M. Temmink, Alfons J. P. Smolders, Conservation Ecology Group, Van der Heide group, and Proceskunde

Subjects

0106 biological sciences, Peat, Sphagnum cuspidatum, Bryophyta, alternative stable states, raised bog, 010603 evolutionary biology, 01 natural sciences, Sphagnum, Article, peat moss, Soil, Alternative stable state, Sphagnopsida, Humans, terrestrialization, Revegetation, Groundwater, Bog, Hydrology, geography, geography.geographical_feature_category, rewetting, Ecology, biology, 010604 marine biology & hydrobiology, Aquatic Ecology, Articles, Vegetation, biology.organism_classification, Moss, Wetlands, Environmental science

Abstract

Globally, peatlands have been affected by drainage and peat extraction, with adverse effects on their functioning and services. To restore peat-forming vegetation, drained bogs are being rewetted on a large scale. Although this practice results in higher groundwater levels, unfortunately it often creates deep lakes in parts where peat was extracted to greater depths than the surroundings. Revegetation of these deeper waters by peat mosses appears to be challenging due to strong abiotic feedbacks that keep these systems in an undesired bare state. In this study, we theoretically explore if a floating peat mat and an open human-made bog lake can be considered two alternative stable states using a simple model, and experimentally test in the field whether stable states are present, and whether a state shift can be accomplished using floating biodegradable structures that mimic buoyant peat. We transplanted two peat moss species into these structures (pioneer sp. Sphagnum cuspidatum and later-successional sp. S. palustre) with and without additional organic substrate. Our model suggests that these open human-made bog lakes and floating peat mats can indeed be regarded as alternative stable states. Natural recovery by spontaneous peat moss growth, i.e., a state shift from open water to floating mats, is only possible when the water table is sufficiently shallow to avoid light limitation (S. cuspidatum and vascular plants. Organic substrate addition particularly facilitated vascular plant growth, which correlated to higher moss height. The structures remained too wet for the late-successional species S. palustre. We conclude that open water and floating peat mats in human-made bog lakes can be considered two alternative stable states, and that temporary floating establishment structures can induce a state shift from the open water state to peat-forming vegetation state. These findings imply that for successful restoration, there is a clear water depth threshold to enable peat moss growth and there is no need for addition of large amounts of donor-peat substrate. Correct species selection for restoration is crucial for success.

Published

2021

12. Mimicry of emergent traits amplifies coastal restoration success

Author

Siti Maryam Yaakub, Eduardo Infantes, Sabine M. Engel, Wouter Lengkeek, Richard K. F. Unsworth, Karine Gagnon, Ralph J.M. Temmink, Christine Angelini, Laura L. Govers, Tjeerd J. Bouma, Leon P. M. Lamers, Karin Didderen, Marjolijn J. A. Christianen, Brian R. Silliman, Nicole Esteban, Jeffrey Gaeckle, Brigitta I. van Tussenbroek, Tjisse van der Heide, Gregory S. Fivash, Christoffer Boström, Marieke M. van Katwijk, Silvija Kipson, Coastal dynamics, Fluvial systems and Global change, Proceskunde, Govers group, Conservation Ecology Group, and Van der Heide group

Subjects

0106 biological sciences, Aquatic Ecology and Water Quality Management, Marsh, Chemistry(all), EROSION, General Physics and Astronomy, 01 natural sciences, Biochemistry, FLUME, Biomimetics, ECOSYSTEMS, lcsh:Science, SEDIMENTATION, Environmental Restoration and Remediation, Netherlands, Multidisciplinary, geography.geographical_feature_category, Ecology, Conservation biology, Zosteraceae, Wetlands ecology, Adaptation, Physiological, Seagrass, PARADIGMS, Salt marsh, FEEDBACKS, Florida, restoration, coastal ecosystem degradation, self-facilitation, emergent traits, seagrass, salt marsh, Restoration ecology, POSITIVE INTERACTIONS, West Indies, Science, Biodegradable Plastics, Hydrocharitaceae, Biology, Physics and Astronomy(all), 010603 evolutionary biology, Article, General Biochemistry, Genetics and Molecular Biology, Temperate climate, Life Science, Seawater, Ecosystem, Civil engineering, 14. Life underwater, Sweden, Tropical Climate, geography, WIMEK, Biochemistry, Genetics and Molecular Biology(all), 010604 marine biology & hydrobiology, Aquatic Ecology, General Chemistry, 15. Life on land, Aquatische Ecologie en Waterkwaliteitsbeheer, biology.organism_classification, FACILITATION, FUNCTIONAL TRAITS, Wetlands, DENSITY, Mimicry, lcsh:Q, Environmental Sciences, Genetics and Molecular Biology(all)

Abstract

Restoration is becoming a vital tool to counteract coastal ecosystem degradation. Modifying transplant designs of habitat-forming organisms from dispersed to clumped can amplify coastal restoration yields as it generates self-facilitation from emergent traits, i.e. traits not expressed by individuals or small clones, but that emerge in clumped individuals or large clones. Here, we advance restoration science by mimicking key emergent traits that locally suppress physical stress using biodegradable establishment structures. Experiments across (sub)tropical and temperate seagrass and salt marsh systems demonstrate greatly enhanced yields when individuals are transplanted within structures mimicking emergent traits that suppress waves or sediment mobility. Specifically, belowground mimics of dense root mats most facilitate seagrasses via sediment stabilization, while mimics of aboveground plant structures most facilitate marsh grasses by reducing stem movement. Mimicking key emergent traits may allow upscaling of restoration in many ecosystems that depend on self-facilitation for persistence, by constraining biological material requirements and implementation costs., Coastal restoration tends to be failure-prone and expensive. Temmink and colleagues improve seagrass and cordgrass transplant survival in field experiments using biodegradable structures which temporarily mimic self-facilitation occurring in mature vegetation stands, and combine onsite and laboratory measurements on sediment stability and stem movement to test the biophysical mechanisms.

Published

2020

13. Evidence for ‘critical slowing down’ in seagrass: a stress gradient experiment at the southern limit of its range

Author

Gregory S. Fivash, Amadou Abderahmane Sall, Laura L. Govers, Theunis Piersma, Han Olff, El-Hacen M. El-Hacen, Tjeerd J. Bouma, Govers group, Olff group, Conservation Ecology Group, and Piersma group

Subjects

0106 biological sciences, Geologic Sediments, STRUCTURAL EQUATION MODELS, Intertidal zone, lcsh:Medicine, Sulfides, 010603 evolutionary biology, 01 natural sciences, Article, ZOSTERA-NOLTII, Alternative stable state, DIE-OFF, Stress, Physiological, Animals, 14. Life underwater, Zostera, lcsh:Science, GeneralLiterature_REFERENCE(e.g.,dictionaries,encyclopedias,glossaries), Ecosystem, Soil Microbiology, TROPICAL SEAGRASS, Multidisciplinary, CLIMATE-CHANGE, Community, biology, 010604 marine biology & hydrobiology, Altitude, Zosteraceae, lcsh:R, Mauritania, Sediment, Aquatic Ecology, RECOVERY, Models, Theoretical, biology.organism_classification, Grassland, Bivalvia, ALTERNATIVE STABLE STATES, FLORIDA BAY, Seagrass, Oceanography, Disturbance (ecology), Biofilms, Environmental science, lcsh:Q, Seasons, BANC-DARGUIN, Accretion (coastal management)

Abstract

The theory of critical slowing down, i.e. the increasing recovery times of complex systems close to tipping points, has been proposed as an early warning signal for collapse. Empirical evidence for the reality of such warning signals is still rare in ecology. We studied this on Zostera noltii intertidal seagrass meadows at their southern range limit, the Banc d’Arguin, Mauritania. We analyse the environmental covariates of recovery rates using structural equation modelling (SEM), based on an experiment in which we assessed whether recovery after disturbances (i.e. seagrass & infauna removal) depends on stress intensity (increasing with elevation) and disturbance patch size (1 m2vs. 9 m2). The SEM analyses revealed that higher biofilm density and sediment accretion best explained seagrass recovery rates. Experimental disturbances were followed by slow rates of recovery, regrowth occurring mainly in the coolest months of the year. Macrofauna recolonisation lagged behind seagrass recovery. Overall, the recovery rate was six times slower in the high intertidal zone than in the low zone. The large disturbances in the low zone recovered faster than the small ones in the high zone. This provides empirical evidence for critical slowing down with increasing desiccation stress in an intertidal seagrass system.

Published

2018