Author
Listed:
- Mads S. Thomsen
(University of Canterbury
Aarhus University)
- Andrew H. Altieri
(Smithsonian Tropical Research Institute
University of Florida)
- Christine Angelini
(University of Florida)
- Melanie J. Bishop
(Macquarie University)
- Fabio Bulleri
(Università di Pisa, CoNISMa)
- Roxanne Farhan
(University of Georgia)
- Viktoria M. M. Frühling
(Smithsonian Tropical Research Institute)
- Paul E. Gribben
(University of New South Wales
Sydney Institute of Marine Science)
- Seamus B. Harrison
(Smithsonian Tropical Research Institute)
- Qiang He
(Fudan University)
- Moritz Klinghardt
(Carl von Ossietzky University Oldenburg)
- Joachim Langeneck
(Università di Pisa, CoNISMa)
- Brendan S. Lanham
(University of New South Wales
Sydney Institute of Marine Science)
- Luca Mondardini
(University of Canterbury)
- Yannick Mulders
(University of Western Australia)
- Semonn Oleksyn
(Macquarie University)
- Aaron P. Ramus
(University of North Carolina Wilmington)
- David R. Schiel
(University of Canterbury)
- Tristan Schneider
(Carl von Ossietzky University Oldenburg)
- Alfonso Siciliano
(University of Canterbury)
- Brian R. Silliman
(Duke University)
- Dan A. Smale
(Marine Biological Association of the United Kingdom, The Laboratory)
- Paul M. South
(Cawthron Institute)
- Thomas Wernberg
(University of Western Australia)
- Stacy Zhang
(Duke University)
- Gerhard Zotz
(Smithsonian Tropical Research Institute
Carl von Ossietzky University Oldenburg)
Abstract
Habitat heterogeneity is considered a primary causal driver underpinning patterns of diversity, yet the universal role of heterogeneity in structuring biodiversity is unclear due to a lack of coordinated experiments testing its effects across geographic scales and habitat types. Furthermore, key species interactions that can enhance heterogeneity, such as facilitation cascades of foundation species, have been largely overlooked in general biodiversity models. Here, we performed 22 geographically distributed experiments in different ecosystems and biogeographical regions to assess the extent to which variation in biodiversity is explained by three axes of habitat heterogeneity: the amount of habitat, its morphological complexity, and capacity to provide ecological resources (e.g. food) within and between co-occurring foundation species. We show that positive and additive effects across the three axes of heterogeneity are common, providing a compelling mechanistic insight into the universal importance of habitat heterogeneity in promoting biodiversity via cascades of facilitative interactions. Because many aspects of habitat heterogeneity can be controlled through restoration and management interventions, our findings are directly relevant to biodiversity conservation.
Suggested Citation
Mads S. Thomsen & Andrew H. Altieri & Christine Angelini & Melanie J. Bishop & Fabio Bulleri & Roxanne Farhan & Viktoria M. M. Frühling & Paul E. Gribben & Seamus B. Harrison & Qiang He & Moritz Kling, 2022.
"Heterogeneity within and among co-occurring foundation species increases biodiversity,"
Nature Communications, Nature, vol. 13(1), pages 1-9, December.
Handle:
RePEc:nat:natcom:v:13:y:2022:i:1:d:10.1038_s41467-022-28194-y
DOI: 10.1038/s41467-022-28194-y
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"Records reveal the vast historical extent of European oyster reef ecosystems,"
Nature Sustainability, Nature, vol. 7(12), pages 1719-1729, December.
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