Going beyond richness: Modelling the BEF relationship using species identity, evenness, richness and species interactions via the DImodels R package

Rafael A. Moral; Rishabh Vishwakarma; John Connolly; Laura Byrne; Catherine Hurley; John A. Finn; Caroline Brophy

doi:10.1111/2041-210X.14158

Methods in Ecology and Evolution (Sep 2023)

Going beyond richness: Modelling the BEF relationship using species identity, evenness, richness and species interactions via the DImodels R package

Rafael A. Moral,
Rishabh Vishwakarma,
John Connolly,
Laura Byrne,
Catherine Hurley,
John A. Finn,
Caroline Brophy

Affiliations

Rafael A. Moral: Department of Mathematics and Statistics Maynooth University Co Kildare Ireland
Rishabh Vishwakarma: School of Computer Science and Statistics, Trinity College Dublin Dublin 2 Ireland
John Connolly: School of Mathematics and Statistics University College Dublin Dublin 4 Ireland
Laura Byrne: School of Computer Science and Statistics, Trinity College Dublin Dublin 2 Ireland
Catherine Hurley: Department of Mathematics and Statistics Maynooth University Co Kildare Ireland
John A. Finn: Department of Environment, Soils and Land Use, Teagasc, Johnstown Castle Wexford Ireland
Caroline Brophy: School of Computer Science and Statistics, Trinity College Dublin Dublin 2 Ireland

DOI: https://doi.org/10.1111/2041-210X.14158
Journal volume & issue: Vol. 14, no. 9
pp. 2250 – 2258

Abstract

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Abstract Biodiversity and ecosystem function (BEF) studies aim to understand how ecosystems respond to a gradient of species diversity. Generalised Diversity‐Interactions (DI) models are suitable for analysing the BEF relationship. These models relate an ecosystem function response of a community to the identity of the species in the community, their evenness (proportions) and interactions. The number of species in the community (richness) is included implicitly in a DI model. It is common in BEF studies to model an ecosystem function as a function of richness; while this can uncover trends in the BEF relationship, by definition, species diversity is broader than richness alone, and important patterns in the BEF relationship may remain hidden. Here, we introduce the DImodels R package for implementing DI models. We show how richness is mathematically equivalent to a simplified DI model under certain conditions, and illustrate how using the DI multidimensional definition of species diversity can provide deeper insight to the BEF relationship compared to traditional approaches. Using DI models can lead to considerably improved model fit over other methods; it does this by incorporating variation due to the multiple facets of species diversity. Predicting from a DI model is not limited to the study design points, the model can interpolate or extrapolate to predict for any species composition and proportions (assuming there is sufficient coverage of this space in the study design). Expressing the BEF relationship as a function of richness alone can be useful to capture overall trends. However, collapsing the multiple dimensions of species diversity to a single dimension (such as richness) can result in valuable ecological information being lost. DI modelling provides a framework to test the multiple components of species diversity in the BEF relationship. It facilitates uncovering a deeper ecological understanding of the BEF relationship and can lead to enhanced inference. The open‐source DImodels R package provides a user‐friendly way to implement this modelling approach.

Published in Methods in Ecology and Evolution

ISSN: 2041-210X (Online)
Publisher: Wiley
Country of publisher: United Kingdom
LCC subjects: Science: Biology (General): Ecology; Science: Biology (General): Evolution
Website: https://besjournals.onlinelibrary.wiley.com/journal/2041210X

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