- Coastal ecosystems dominated by foundation species
- Feedbacks between organisms and their environment (ecosystem engineering)
- Ecological interactions between foundation species and the associated community
- Ecosystem conservation and restoration
- cological modelling, biogeochemistry
Prof. Dr. Ir. Tjisse van der Heide
‘Soft-sediment coasts with long ecological gradients have a lot to offer both nature and people’
Tjisse van der Heide, professor of Coastal Ecology, studies ecological interactions along the entire elevational gradient of soft-sediment coasts: from coastal dunes, salt marshes and intertidal mudflat all the way down into the subtidal which never emerges during low tide. ‘These shallow coastal areas are important, because they protect our coasts, serve as drinking water sources, and support many different plant and animal species. In contrast to rocky shores, that are characterized by steep gradients from high to low, healthy soft-sediment coasts typically have long elevational gradients supporting a diverse mosaic of coastal habitats. However, as a consequence of coastal development on one side and sea level rise on the other, humans have restricted these long gradients into a progressively narrowing coastal strip – a process called the ‘coastal squeeze’. This is resulting in great loss of coastal habitat and the functions and services they provide’
Ecosystem engineers
Within these coastal zones, my work primarily focuses on how habitat-modifying species, often called ‘ecosystem engineers’ or ‘foundation species’, shape coastal landscapes. In coastal dunes, for instance, I aim to understand how clonally growing grasses accumulate sand to build dunes, allowing them to escape stress from flooding by seawater. On intertidal flat and in the subtidal, I study seagrasses and mussels that form large beds that attenuate waves and accumulate sediment particles, thereby building a landscape that not only benefits the engineering species, but also a biodiverse associated community.
Conserving and restoring ecosystem services
Ecosystem engineers are not only important from an ecological perspective, given that humans are definitely amongst the many species that profit from the landscapes they build. Coastal ecosystem engineers provide important ‘ecosystem services’. Their landscapes, for instance, offer protection against flooding during storms, decreasing the impact on man-made defences such as dikes, while simultaneously serving as carbon sinks, and as foraging and nursery areas for commercially important species. Because of their great ecological and societal relevance, we are therefore not only trying to elucidate how they function, but also figure out how we can restore lost or degraded ecosystems. To achieve this, we are developing biodegradable establishment structures that temporarily mimic the landscape modifying traits of ecosystem engineers, allowing the actual species to establish and take over as the structures naturally degrade’.
Read more +
Interests
Research interests
I will be joining COS at NIOZ combined with a position at the University of Groningen starting from the 1st of January 2018. My work focuses primarily on (1) causes and consequences of coastal ecosystem degradation, and (2) development of novel applications to preserve and/or restore coastal ecosystems.
Central in the first research line is the ecosystem-level importance and functioning of habitat modifying species – also called 'ecosystem engineers' or 'foundation species'. These organisms often facilitate themselves and the associated community by improving their environment through density- and patch size-dependent feedbacks. Clear examples are reef-building bivalves, seagrasses, salt marsh plants, and dune-building plants that attenuate currents and waves, increase water clarity, and modify sediment conditions.
My second line builds on the first with the aim of extending fundamental findings to develop applications for preserving or restoring coastal ecosystems. Examples are recent work on the inclusion of both intra- (within species) and interspecific (between species) facilitation restoration into designs, and the development of temporary biodegradable structures that bridge establishment thresholds for habitat-modifying species.
Functions
Functions
Publications
Key-publications
Please find my complete list of NIOZ-publications at the bottom of this webpage or on ResearcherID. You can download all my publications on ResearchGate.
Education
Professional education
Awards
Awards, prizes and funded
2018: NWO Vidi-Award 'Building coastal landscapes with spatially organizing plants'
Other
Other
Linked news
Wednesday 16 November 2022
Tree reefs become oases of life in the subtidal Wadden Sea
Researchers from the Royal Netherlands Institute for Sea Research (NIOZ), the University of Groningen, and Utrecht University have constructed artificial reefs made of pear-trees in the subtidal Dutch Wadden Sea in a novel experiment as part of the…
Tuesday 18 October 2022
Microphytobenthos in the Dutch Wadden Sea feeds on ‘left-overs’ in the bottom
The Wadden Sea is an extremely productive ecosystem whose food web is supported by benthic organisms, feeding on primary producers. In a recent publication in Frontiers of Ecology and Evolution, NIOZ marine biogeochemist dr. Philip Riekenberg and…
Monday 22 August 2022
Nature compensation for Maasvlakte 2 still not realized
The nature compensation for the construction of Maasvlakte 2, as agreed with the government in 2008, has not actually been realized. That is the conclusion that coastal ecologist Professor Tjisse van der Heide draws in a memorandum he wrote after…
Monday 22 August 2022
EU-Horizon Europe funding for ACTNOW project
Human activities have created unprecedented, cumulative threats resulting in stunning losses of biodiversity in our oceans. This is leading to well‐documented declines in seafood resources, losses of iconic and culturally valuable habitats, and…
Tuesday 14 June 2022
Restoring marine nature by 'planting' pear tree reefs
In the past century, many reefs in the Wadden Sea and North Sea have disappeared. Reefs are very important for fish because they can hide there. We therefore need to restore reefs, but how do we do that? NIOZ is now starting a study into the…
Wednesday 04 May 2022
Land-building marsh plants are champions of CO2 capture
It is well known that CO2 emissions from burning fossil fuels underlie the havoc being wrought by climate change. Stemming further emissions through innovations in sustainable energy production is certainly part of the solutions. However, slowing…
Tuesday 26 April 2022
Researchers restore shellfish reefs with 3D printed artificial reefs
Next month the project "Building with Ecosystem Engineers" will start with the aim of restoring mussel and oyster reefs in the Wadden Sea. The innovative research project of NIOZ and Utrecht University will 3D print artificial reef structures made of…
Monday 28 February 2022
IPPC report on climate adaptation
Today the IPCC published their newest report on climate change and climate adaptation. It analyses the impacts of the climate crisis and how humanity can adapt, in addition to slashing emissions. The good news is that a liveable future remains within…
Friday 10 September 2021
SIBES and Wadden Mosaic show powerline Wadden Sea planned straight through biodiversity hotspots
The projected powerline ‘Eemshaven West’, that may connect a new 700 MW wind park on the North Sea with the powerstation in Eemshaven, potentially crosses the Wadden Sea exactly in some of the most biodiverse hotspots. That is the conclusion drawn by…
Wednesday 23 September 2020
Caribbean islands face loss of protection and biodiversity as seagrass loses terrain
Tropical islands have an important ally when it comes to battling storms and sea-level rise: seagrass. During hurricane Irma, an extremely powerful Category 5 storm that hit the North Caribbean in 2017, NIOZ scientist Rebecca James witnessed how…
Linked blogs
Monday 15 May 2023
Marine biodiversity in the Ems Dollart area
As part of the project Wadden Mosaic, the habitats and biodiversity of the subtidal Wadden are mapped for the first time - the part of the Dutch Wadden Sea that is permanently submerged. The Wadden Sea is a nature area of international and national…
Wednesday 21 July 2021
Fieldwork Schiermonnikoog - mapping oyster and mussel reefs
In my line of work it is not common to get asked to accompany a fieldwork expedition. This is surprising, as a lot of the people working at NIOZ can be found in the field (or more usually, on the water) at some point in time. For a…
Thursday 17 December 2020
NIOZ Podcast Van Delta tot Diepzee aflevering 6 Schelpdieren en planten als ingenieurs
Kustecoloog professor Tjisse van der Heide onderzoekt het grensgebied tussen land en zee: van de duinen via de kwelders en de zandplaten tot op de bodem van de geulen. Hij doet onderzoek naar ecosytem-engineers. Dat wil zeggen, naar beesten en…
Thursday 03 September 2020
ReViFES fieldwork 2020 | Investigating North Sea reefs services
Biogenic reefs are hard structures built by living organisms which form complex ecosystems and are accountable for several important ecological functions. In the North Sea, the most common bio-constructors include bivalves, such as oysters and…
NIOZ publications
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2023
Bakker, J.P.; Berg, M.P.; Grootjans, A.P.; Olff, H.; Schrama, M.; Reijers, V.C.; van der Heide, T (2023). Biogeomorphological aspects of a model barrier island and its surroundings - Interactions between abiotic conditions and biota shaping the tidal and terrestrial landscape: A synthesis. Ocean Coast. Manag. 239: 106624. https://dx.doi.org/10.1016/j.ocecoaman.2023.106624Cronau, R.J.T.; Telgenkamp, Y.; de Fouw, J; van Katwijk, M.M.; Bouma, T.; Heusinkveld, J.H.T.; Hoeijmakers, D.; van der Heide, T.; Lamers, L.P.M. (2023). Seagrass is protected from ragworm pressure by a newly discovered grazer–ragworm interaction; implications for restoration. J. Appl. Ecol. 60(6): 978-989. https://dx.doi.org/10.1111/1365-2664.14381de Fouw, J; Holmer, M.; Beca-Carretero, P.; Boström, C.; Brice, J.; Brun, F.G.; Cruijsen, P.M.J.M.; Govers, L.L.; Garmendia, J.M.; Meysick, L.; Pajusalu, L.; Richir, J.; Robroek, B.J.M.; Valle, M.; van der Ven, P.; Eklöf, J.S.; van der Heide, T. (2023). A facultative mutualism facilitates European seagrass meadows. Ecography 2023(5): e06636. https://dx.doi.org/10.1111/ecog.06636Eijsackers, H.J.P.; Eriksson, B.D.H.K.; van der Heide, T.; Herman, P.M.J.; van der Meer, J.; Polet, H.; Tulp, I. (2023). Beoordeling van ecologische effecten van garnalenvisserij op bodem en biota : Mate van wetenschappelijke onderbouwing. Rapport nummer:C056/23. Wageningen Marine Research & Waddenacademie: IJmuiden. ISBN 978-94-90289-70-6. 53 pp. https://dx.doi.org/10.18174/637595
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2022
Cronau, R.J.T.; de Fouw, J; van Katwijk, M.M.; Bouma, T.J.; Heusinkveld, J.H.T.; Hoeijmakers, D.; Lamers, L.P.M.; van der Heide, T. (2023). Seed‐ versus transplant‐based eelgrass (Zostera marinaL.) restoration success in a temperate marine lake. Restor. Ecol. 31(1): e13786. https://dx.doi.org/10.1111/rec.13786de Fouw, J.; Rehlmeyer, K.; van der Geest, M.; Smolders, A.J.P.; van der Heide, T. (2022). Increased temperature reduces the positive effect of sulfide-detoxification mutualism on Zostera noltii nutrient uptake and growth. Mar. Ecol. Prog. Ser. 692: 43-52. https://dx.doi.org/10.3354/meps14074Fivash, G.S.; van Belzen, J.; Temmink, R.J.M.; Didderen, K.; Lengkeek, W.; van der Heide, T.; Bouma, T.J. (2022). Increasing spatial dispersion in ecosystem restoration mitigates risk in disturbance‐driven environments. J. Appl. Ecol. 59(4): 1050-1059. https://dx.doi.org/10.1111/1365-2664.14116Govers, L.L.; Heusinkveld, J.H.T.; Gräfnings, M.L.E.; Smeele, Q.; van der Heide, T. (2022). Adaptive intertidal seed-based seagrass restoration in the Dutch Wadden Sea. PLoS One 17(2): e0262845. https://dx.doi.org/10.1371/journal.pone.0262845Gräfnings, M.L.E.; Heusinkveld, J.H.T.; Hoeijmakers, D.J.J.; Smeele, Q.; Wiersema, H.; Zwarts, M.; van der Heide, T.; Govers, L.L. (2023). Optimizing seed injection as a seagrass restoration method. Restor. Ecol. 31(3): e13851. https://dx.doi.org/10.1111/rec.13851Infantes, E.; Hoeks, S.; Adams, M.P.; van der Heide, T.; van Katwijk, M.M.; Bouma, T.J. (2022). Seagrass roots strongly reduce cliff erosion rates in sandy sediments. Mar. Ecol. Prog. Ser. 700: 1-12. https://doi.org/10.3354/meps14196MacDonnell, C.; Tiling, K.; Encomio, V.; van der Heide, T.; Teunis, M.; Wouters, L.; Didderen, K.; Bouma, T.J.; Inglett, P.W. (2022). Evaluating a novel biodegradable lattice structure for subtropical seagrass restoration. Aquat. Bot. 176: 103463. https://dx.doi.org/10.1016/j.aquabot.2021.103463Meijer, K.J.; Franken, O.; van der Heide, T.; Holthuijsen, S.; Visser, W.; Govers, L.L.; Olff, H. (2023). Characterizing bedforms in shallow seas as an integrative predictor of seafloor stability and the occurrence of macrozoobenthic species. Remote Sensing in Ecology and Conservation 9(3): 323-339. https://dx.doi.org/10.1002/rse2.312Riekenberg, P.M.; van der Heide, T.; Holthuijsen, S.; van der Veer, H.W.; van der Meer, M.T.J. (2022). Compound-specific stable isotope analysis of amino acid nitrogen reveals detrital support of microphytobenthos in the Dutch Wadden Sea benthic food web. Front. Ecol. Evol. 10: 951047. https://dx.doi.org/10.3389/fevo.2022.951047Temmink, R.J.M.; Fivash, G.S.; Govers, L.L.; Nauta, J.; Marín Díaz, B.; Cruijsen, P.M.J.M.; Didderen, K.; Penning, E.; Olff, H.; Heusinkveld, J.H.T.; Lamers, L.P.M.; Lengkeek, W.; Christianen, M.J.A.; Reijers, V.C.; Bouma, T.J.; van der Heide, T. (2022). Initiating and upscaling mussel reef establishment with life cycle informed restoration: Successes and future challenges. Ecol. Eng. 175: 106496. https://dx.doi.org/10.1016/j.ecoleng.2021.106496Temmink, 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. (2022). Recovering wetland biogeomorphic feedbacks to restore the world’s biotic carbon hotspots. Science (Wash.) 376(6593): eabn1479. https://dx.doi.org/10.1126/science.abn1479
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2021
Chin, D.W.; de Fouw, J; van der Heide, T.; Cahill, B.V.; Katcher, K.; Paul, V.J.; Campbell, J.E.; Peterson, B.J. (2021). Facilitation of a tropical seagrass by a chemosymbiotic bivalve increases with environmental stress. J. Ecol. 109(1): 204-217. https://doi.org/10.1111/1365-2745.13462Fivash, G.S.; Stüben, D.; Bachmann, M.; Walles, B.; van Belzen, J.; Didderen, K.; Temmink, R.J.M.; Lengkeek, W.; van der Heide, T.; Bouma, T.J. (2021). Can we enhance ecosystem-based coastal defense by connecting oysters to marsh edges? Analyzing the limits of oyster reef establishment. Ecol. Eng. 165: 106221. https://doi.org/10.1016/j.ecoleng.2021.106221Fivash, G.S.; Temmink, R.J.M.; D’Angelo, M.; van Dalen, J.; Lengkeek, W.; Didderen, K.; Ballio, F.; van der Heide, T.; Bouma, T.J. (2021). Restoration of biogeomorphic systems by creating windows of opportunity to support natural establishment processes. Ecol. Appl. 31(5): e02333. https://doi.org/10.1002/eap.2333Gagnon, K.; Christie, H.C.; Didderen, K.; Fagerli, C.W.; Govers, L.L.; Gräfnings, M.L.E.; Heusinkveld, J.H.T.; Kaljurand, K.; Lengkeek, W.; Martin, G.; Meysick, L.; Pajusalu, L.; Rinde, E.; van der Heide, T.; Boström, C. (2021). Incorporating facilitative interactions into small‐scale eelgrass restoration—challenges and opportunities. Restor. Ecol. 29(5): e13398. https://doi.org/10.1111/rec.13398Gilby, B.L.; Olds, A.D.; Chapman, S.; Goodridge Gaines, L.A.; Henderson, C.J.; Ortodossi, N.L.; Didderen, K.; Lengkeek, W.; van der Heide, T.; Schlacher, T.A. (2021). Attraction versus production in restoration: spatial and habitat effects of shellfish reefs for fish in coastal seascapes. Restor. Ecol. 29(7): e13413. https://dx.doi.org/10.1111/rec.13413Marín Díaz, B.; Fivash, G.S.; Nauta, J.; Temmink, R.J.M.; Hijner, N.; Reijers, V.C; Cruijsen, P.M.J.M.; Didderen, K.; Heusinkveld, J.H.T.; Penning, E.; Maldonado-Garcia, G.; van Belzen, J.; de Smit, J.C.; Christianen, M.J.A.; van der Heide, T.; van der Wal, D.; Olff, H.; Bouma, T.J.; Govers, L.L. (2021). On the use of large-scale biodegradable artificial reefs for intertidal foreshore stabilization. Ecol. Eng. 170: 106354. https://dx.doi.org/10.1016/j.ecoleng.2021.106354Reijers, 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. (2021). Sediment availability provokes a shift from Brownian to Lévy‐like clonal expansion in a dune building grass. Ecol. Lett. 24(2): 258-268. https://doi.org/10.1111/ele.13638Temmink, R.J.M.; Angelini, C.; Fivash, G.S.; Swart, L.; Nouta, R.; Teunis, M.; Lengkeek, W.; Didderen, K.; Lamers, L.P.M.; Bouma, T.J.; van der Heide, T. (2021). Life cycle informed restoration: Engineering settlement substrate material characteristics and structural complexity for reef formation. J. Appl. Ecol. 58(10): 2158-2170. https://dx.doi.org/10.1111/1365-2664.13968Temmink, R.J.M.; Cruijsen, P.M.J.M.; Smolders, A.J.P.; Bouma, T.J.; Fivash, G.S.; Lengkeek, W.; Didderen, K.; Lamers, L.P.M.; van der Heide, T. (2021). Overcoming establishment thresholds for peat mosses in human‐made bog pools. Ecol. Appl. 31(6): e02359. https://dx.doi.org/10.1002/eap.2359Temmink, R.J.M.; Dorenbosch, M.; Lamers, L.P.M.; Smolders, A.J.P.; Rip, W.; Lengkeek, W.; Didderen, K.; Fivash, G.S.; Bouma, T.J.; van der Heide, T. (2021). Growth forms and life-history strategies predict the occurrence of aquatic macrophytes in relation to environmental factors in a shallow peat lake complex. Hydrobiologia 848(17): 3987-3999. https://doi.org/10.1007/s10750-021-04618-6van der Heide, T.; Angelini, C.; de Fouw, J.; Eklöf, J.S. (2021). Facultative mutualisms: a double‐edged sword for foundation species in the face of anthropogenic global change. Ecol. Evol. 11(1): 29-44. https://doi.org/10.1002/ece3.7044van 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. (2021). Coastal restoration success via emergent trait-mimicry is context dependent. Biol. Conserv. 264: 109373. https://dx.doi.org/10.1016/j.biocon.2021.109373van der Molen, J.; van Leeuwen, S.M.; Govers, L.L.; van der Heide, T.; Olff, H. (2021). Potential micro-plastics dispersal and accumulation in the North Sea, with application to the MSC Zoe incident. Front. Mar. Sci. 8: 607203. https://doi.org/10.3389/fmars.2021.607203Yan, J.; Zhu, Z.; Zhou, J.; Chu, X.; Sui, H.; Cui, B.; van der Heide, T. (2021). Saltmarsh resilience controlled by patch size and plant density of habitat-forming species that trap shells. Sci. Total Environ. 778: 146119. https://doi.org/10.1016/j.scitotenv.2021.146119Zhang, Y.S.; Gittman, R.K.; Donaher, S.E.; Trackenberg, S.N.; van der Heide, T; Silliman, B.R. (2021). Inclusion of intra- and interspecific facilitation expands the theoretical framework for seagrass restoration. Front. Mar. Sci. 8: 645673. https://doi.org/10.3389/fmars.2021.645673
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2020
de Fouw, J.; van der Zee, E.M.; van Gils, J.A.; Eriksson, B.K.; Weerman, E.; Donadi, S.; van der Veer, H.W.; Olff, H.; Piersma, T.; van der Heide, T. (2020). The interactive role of predation, competition and habitat conditions in structuring an intertidal bivalve population. J. Exp. Mar. Biol. Ecol. 523: 151267. https://dx.doi.org/10.1016/j.jembe.2019.151267Fivash, G.S.; van Belzen, J.; Temmink, R.J.M.; Didderen, K.; Lengkeek, W.; van der Heide, T.; Bouma, T.J. (2020). Elevated micro-topography boosts growth rates in Salicornia procumbens by amplifying a tidally-driven oxygen pump: implications for natural recruitment and restoration. Ann. Bot. 125(2): 277-290. https://dx.doi.org/10.1093/aob/mcz137Gagnon, 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. (2020). Facilitating foundation species: The potential for plant–bivalve interactions to improve habitat restoration success. J. Appl. Ecol. 57(6): 1161-1179. https://dx.doi.org/10.1111/1365-2664.13605James, R.K.; van Katwijk, M.M.; van Tussenbroek, B.I.; van der Heide, T.; Dijkstra, H.A.; van Westen, R.M.; Pietrzak, J.D.; Candy, A.S.; Klees, R.; Riva, R.E.M.; Slobbe, C.D.; Katsman, C.A.; Herman, P.M.J.; Bouma, T.J. (2020). Water motion and vegetation control the pH dynamics in seagrass‐dominated bays. Limnol. Oceanogr. 65(2): 349-362. https://dx.doi.org/10.1002/lno.11303Reijers, V.C; Lammers, C.; de Rond, A.J.A.; Hoetjes, S.C.S.; Lamers, L.P.M.; van der Heide, T. (2020). Resilience of beach grasses along a biogeomorphic successive gradient: resource availability vs. clonal integration. Oecologia 192: 201–212. https://dx.doi.org/10.1007/s00442-019-04568-wTemmink, R. J. M.; Christianen, M. J. A.; Fivash, G. S.; Angelini, C.; Boström, C.; Didderen, K.; Engel, S. M.; Esteban, N.; Gaeckle, J. L.; Gagnon, K.; Govers, L. L.; Infantes, E.; van Katwijk, M. M.; Kipson, S.; Lamers, L. P. M.; Lengkeek, W.; Silliman, B. R.; van Tussenbroek, B. I.; Unsworth, R. K. F.; Yaakub, S. M.; Bouma, T. J.; van der Heide, T. (2020). Mimicry of emergent traits amplifies coastal restoration success. Nature Comm. 11(1): 3668. https://dx.doi.org/10.1038/s41467-020-17438-4Valdez, S.R.; Zhang, Y.S.; van der Heide, T.; Vanderklift, M.A.; Tarquinio, F.; Orth, R.J.; Silliman, B.R. (2020). Positive ecological interactions and the success of seagrass restoration. Front. Mar. Sci. 7: article 9. https://dx.doi.org/10.3389/fmars.2020.00091van Bergen, T.J.H.M.; Temmink, R.J.M.; van Tweel-Groot, L.; Bakker, W.J.; Rehlmeyer, K.; Koks, A.H.W.; Waajen, A.C.; Roelofs, J.G.M.; Grootjans, A.P.; van der Heide, T.; Lamers, L.P.M. (2020). Self‐facilitation and negative species interactions could drive microscale vegetation mosaic in a floating fen. J. Veg. Sci. 31(2): 343-354. https://dx.doi.org/10.1111/jvs.12851van der Geest, M.; van der Heide, T.; Holmer, M.; De Wit, R. (2020). First field-based evidence that the seagrass-lucinid mutualism can mitigate sulfide stress in seagrasses. Front. Mar. Sci. 7: 11. https://dx.doi.org/10.3389/fmars.2020.00011Yan, J.; van der Heide, T.; Cui, B.; Bai, J.; Ysebaert, T.; van de Koppel, J. (2020). A healthy trophic structure underlies the resistance of pristine seagrass beds to nutrient enrichment. Limnol. Oceanogr. 65(11): 2748-2756. https://dx.doi.org/10.1002/lno.11545
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2019
Borst, A.C.W.; Angelini, C.; Berge; Lamers, L.P.M.; Derksen-Hooijberg, M.; van der Heide, T. (2019). Food or furniture: Separating trophic and non‐trophic effects of Spanish moss to explain its high invertebrate diversity. Ecosphere 10(9): e02846. https://dx.doi.org/10.1002/ecs2.2846Chalifour, B.; Hoogveld, J.R.H.; Derksen-Hooijberg, M.; Harris, K.L.; Urueña, J.M.; Sawyer, W.G.; van der Heide, T; Angelini, C. (2019). Drought alters the spatial distribution, grazing patterns, and radula morphology of a fungal-farming salt marsh snail. Mar. Ecol. Prog. Ser. 620: 1-13. https://dx.doi.org/10.3354/meps12976Derksen-Hooijberg, M.; Angelini, C.; Hoogveld, J.R.H.; Lamers, L.P.M.; Borst, A.; Smolders; Harpenslager; Govers, L.L.; van der Heide, T. (2019). Repetitive desiccation events weaken a salt marsh mutualism. J. Ecol. 107(5): 2415-2426. https://dx.doi.org/10.1111/1365-2745.13178Derksen-Hooijberg, M.; van der Heide, T.; Lamers, L.P.M.; Borst, A.; Smolders, A.J.P.; Govers, L.; Hoogveld, J.R.H.; Angelini, C. (2019). Burrowing Crabs Weaken Mutualism Between Foundation Species. Ecosystems 22(4): 767–780. https://doi.org/10.1007/s10021-018-0301-xJames, R.K.; Silva, R.; van Tussenbroek, B.I.; Escudero-Castillo, M.; Mariño-Tapia, I.; Dijkstra, H.A.; van Westen, R.M.; Pietrzak, J.D.; Candy, A.S.; Katsman, C.A.; van der Boog, C.G.; Riva, R.E.M.; Slobbe, C.; Klees, R.; Stapel, J.; van der Heide, T.; van Katwijk, M.M.; Herman, P.M.J.; Bouma, T.J. (2019). Maintaining tropical beaches with seagrass and algae: a promising alternative to engineering solutions. BioScience 69(2): 136-142. https://dx.doi.org/10.1093/biosci/biy154Reijers, V.C.; Cruijsen; Hoetjes; Akker; Heusinkveld, J.H.T.; van de Koppel, J.; Lamers, L.P.M.; Olff, H.; van der Heide, T. (2019). Loss of spatial structure after temporary herbivore absence in a high‐productivity reed marsh. J. Appl. Ecol. 56(7): 1817-1826. https://dx.doi.org/10.1111/1365-2664.13394Reijers, V.C.; Siteur, K.; Hoeks, S.; van Belzen, J.; Borst, A.C.W.; Heusinkveld, J.H.T.; Govers, L.; Bouma, T.J.; Lamers, L.P.M.; van de Koppel, J.; van der Heide, T. (2019). A Lévy expansion strategy optimizes early dune building by beach grasses. Nature Comm. 10: 2656. https://dx.doi.org/10.1038/s41467-019-10699-8Reijers, V.C.; van den Akker, M.; Cruijsen, P.M.J.M.; Lamers, L.P.M.; van der Heide, T. (2019). Intraspecific facilitation explains the persistence of Phragmites australis in modified coastal wetlands . Ecosphere 10(8): e02842. https://dx.doi.org/10.1002/ecs2.2842
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2018
Bom, R.A.; Philippart, C.J.M.; van der Heide, T.; de Fouw, J; Camphuysen, C.J.; Dethmer, K.; Folmer, E.O.; Stocchi, P.; Stuut, J.-B.; van der Veer, H.W.; Al Zakwani, I. (2018). Barr Al Hikman: a pristine coastal ecosystem in the Sultanate of Oman: Current state of knowledge and future research challenges. NIOZ-rapport, 2018(1). NIOZ Royal Institute for Sea Research: Texel. 61 pp.Borst, A.C.W.; Verberk, W.C.E.P.; Angelini, C.; Schotanus, J.; Wolters, J.-W.; Christianen, M.J.A.; van der Zee, E.M.; Derksen-Hooijberg, M.; van der Heide, T. (2018). Foundation species enhance food web complexity through non-trophic facilitation. PLoS One 13(8): e0199152. https://doi.org/10.1371/journal.pone.0199152de Fouw, J; van der Heide, T.; van Belzen, J.; Govers, L.; Cheikh, M.A.S.; Olff, H.; van de Koppel, J.; van Gils, J.A. (2018). A facultative mutualistic feedback enhances the stability of tropical intertidal seagrass beds. NPG Scientific Reports 8(1): 10. https://doi.org/10.1038/s41598-018-31060-x
Linked projects
Small steps, giant leaps
Supervisor
Tjisse van der Heide
Funder
Netherlands Organization for Scientific Research - Veni/Vidi/Vici
Project duration
1 Jul 2018 - 30 Jun 2023
