- Noam Altman-Kurosaki1 - Email: naltmank@gmail.com LTER: Moorea Coral Reef
- Katherine Hulting2,3 - Email: hultingk@msu.edu LTER: Kellogg Biological Station
- Pooja Panwar4 - Email: Pooja.Panwar.GR@dartmouth.edu LTER: Hubbard Brook Research Forest
- Julianna Renzi5 - Email: jrenzi@ucsb.edu LTER: Moorea Coral Reef
- Dr. Kelsey Solomon6 - Email: ksolomon@fiu.edu LTER: Florida Coastal Everglades, Coweeta
- James Sturges7- Email: jstur015@fiu.edu LTER: Florida Coastal Everglades
- Dr. Junna Wang8- Email: junna.wang@yale.edu LTER: Harvard Forest
- School of Biological Sciences, Georgia Institute of Technology, 311 Ferst Drive, Atlanta, GA 30332
- W.K. Kellogg Biological Station, Michigan State University, 3700 Gull Lake Dr, Hickory Corners 49060
- Department of Integrative Biology and Ecology, Evolution, and Behavior, Michigan State University, 288 Farm Ln, East Lansing, MI 48824
- Ecology, Evolution, Environment, and Society, Dartmouth College, 78 College St, Hanover, NH 03755
- Department of Ecology, Evolution, and Marine Biology, University of California Santa Barbara, UCEN Road Building 535, Goleta, CA 93117
- Institute of Environment and Department of Biology, Florida International University, 11200 SW 8th Street Miami, FL 33199
- Department of Earth and Environment and Institute of Environment, Florida International University, 11200 SW 8th Street Miami, FL 33199
- School of the Environment, Yale University, 195 Prospect St, New Haven, CT 06511
How does the strength and direction of diversity-stability relationships vary (1) among ecosystems and (2) between ecosystem-level and community-level stability?
Diversity-stability relationships are a foundation of community ecology but are controversial and highly debated. Historically, studies have focused on the stability of land-plant communities, focusing on how species richness promotes the stability of primary production or above-ground biomass (hereafter “ecosystem stability”). However, these studies may neglect underlying changes in community composition (hereafter “community stability”). As the biodiversity crisis worsens, understanding the strength and direction of biodiversity-stability relationships across multiple ecosystems and multiple facets of stability will be critical in predicting implications of biodiversity change. Additionally, the strength and direction of diversity-stability relationships may differ with the degree of abiotic variability in a system, but less research has compared diversity-stability relationships in multiple ecosystems.
We will gather long-term (>10 year) time series of primary producer communities across ecosystem types (e.g., grassland, forest, lake, kelp forest, coral reef) from the LTER network. Using this harmonized dataset, we will compare the diversity (i.e., taxonomic richness, functional richness, evenness) of the producer communities at sites within each LTER with the ecosystem-level and community-level stability (see key definitions) of those sites. We will then compare the direction and slopes of these relationships among LTER sites to explore (1) how these relationships vary among environments and (2) how diversity differentially influences ecosystem-level versus community-level stability.
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Ecosystem stability: The extent to which production is constant through time. We will calculate ecosystem stability as the inverse of the coefficient of variation of producer abundance (e.g., biomass, cover) throughout the time series.
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Community stability: The extent to which structural community composition is constant through time. We will calculate community stability as a function of the vector length in multivariate space between consecutive biological community matrices.
- We will briefly describe the purpose of each of our scripts here as we create them--stay tuned!
You can see our recommended guidelines for contribution and style guide on our CONTRIBUTIONS.md
- LTER Scientific Computing Team: website
- NCEAS' Resources for Working Groups
