TY - JOUR
T1 - Biodegradable artificial reefs enhance food web complexity and biodiversity in an intertidal soft-sediment ecosystem
AU - Nauta, Janne
AU - Christianen, Marjolijn J.A.
AU - Temmink, Ralph J.M.
AU - Fivash, Gregory S.
AU - Marin-Diaz, Beatriz
AU - Reijers, Valérie C.
AU - Didderen, Karin
AU - Penning, Emma
AU - Borst, Annieke C.W.
AU - Heusinkveld, Jannes H.T.
AU - Zwarts, Maarten
AU - Cruijsen, Peter M.J.M.
AU - Hijner, Nadia
AU - Lengkeek, Wouter
AU - Lamers, Leon P.M.
AU - van der Heide, Tjisse
AU - Bouma, Tjeerd J.
AU - van der Wal, Daphne
AU - Olff, Han
AU - Govers, Laura L.
N1 - Funding Information:
We thank all volunteers, students and professionals who helped in setting-up and monitoring the experiment for their enthusiasm and hard work. In special, thanks to Henk Wiersma from the Fieldwork Company for all his inventions; Jouke, Sien and Saar for hosting us on the Ambulant; the crew of the Asterias from the ‘Wadden Unit’ for transportation; and Paul van der Ven (Radboud University) for analysing all stable isotope samples. In addition, we would like to thank the editors, anonymous reviewer and Dominic McAfee for their constructive comments in the previous version of this manuscript. We thank the province of Fryslân for research permits (R. Deen) and Natuurmonumenten (Q. Smeele, E. Jansen, JW. Zwart) for site access. R.J.M.T., G.S.F., K.D., W.L., T.J.B. and T.v.d.H were funded by NWO/TTW- OTP grant 14424, in collaboration with private and public partners: Natuurmonumenten, STOWA, Rijkswaterstaat, Van Oord, Bureau Waardenburg, Enexio and Rodenburg Biopolymers. H.O., E.P and L.L.G were funded by a grant from Waddenfonds and Rijkswaterstaat, for the project ‘dynamic Griend’. T.v.d.H, L.L.G and V.R.R. were additionally funded by OBN. B.M.D. and T.J.B. were funded by NWO/TTW All Risk grant P15-21 B1. T.v.d.H. was funded by NWO/ TTW-Vidi grant 16588. M.J.A.C. was funded by EU-H2020 project MERCES grant 689518. L.L.G. was funded by NWO-VENI grant 016. Veni.181.087.
Funding Information:
We thank all volunteers, students and professionals who helped in setting‐up and monitoring the experiment for their enthusiasm and hard work. In special, thanks to Henk Wiersma from the Fieldwork Company for all his inventions; Jouke, Sien and Saar for hosting us on the Ambulant; the crew of the Asterias from the ‘Wadden Unit’ for transportation; and Paul van der Ven (Radboud University) for analysing all stable isotope samples. In addition, we would like to thank the editors, anonymous reviewer and Dominic McAfee for their constructive comments in the previous version of this manuscript. We thank the province of Fryslân for research permits (R. Deen) and Natuurmonumenten (Q. Smeele, E. Jansen, JW. Zwart) for site access. R.J.M.T., G.S.F., K.D., W.L., T.J.B. and T.v.d.H were funded by NWO/TTW‐ OTP grant 14424, in collaboration with private and public partners: Natuurmonumenten, STOWA, Rijkswaterstaat, Van Oord, Bureau Waardenburg, Enexio and Rodenburg Biopolymers. H.O., E.P and L.L.G were funded by a grant from Waddenfonds and Rijkswaterstaat, for the project ‘dynamic Griend’. T.v.d.H, L.L.G and V.R.R. were additionally funded by OBN. B.M.D. and T.J.B. were funded by NWO/TTW All Risk grant P15‐21 B1. T.v.d.H. was funded by NWO/ TTW‐Vidi grant 16588. M.J.A.C. was funded by EU‐H2020 project MERCES grant 689518. L.L.G. was funded by NWO‐VENI grant 016. Veni.181.087.
Publisher Copyright:
© 2022 The Authors. Journal of Applied Ecology published by John Wiley & Sons Ltd on behalf of British Ecological Society.
PY - 2023/3
Y1 - 2023/3
N2 - 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).
AB - 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).
KW - artificial reefs
KW - biogenic reefs
KW - coastal restoration
KW - ecological networks
KW - food web complexity
KW - foundation species
KW - mussel
KW - self-facilitation
UR - http://www.scopus.com/inward/record.url?scp=85145458741&partnerID=8YFLogxK
U2 - 10.1111/1365-2664.14348
DO - 10.1111/1365-2664.14348
M3 - Article
AN - SCOPUS:85145458741
SN - 0021-8901
VL - 60
SP - 541
EP - 552
JO - Journal of Applied Ecology
JF - Journal of Applied Ecology
IS - 3
ER -