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Biome classification influences current and projected future biome distributions

Simon Scheiter, Dushyant Kumar, Mirjam Pfeiffer, Liam Langan

2023Global Ecology and Biogeography16 citationsDOIOpen Access PDF

Abstract

Abstract Aim Biome classification schemes are widely used to map biogeographic patterns of vegetation formations on large spatial scales. Future climate change will influence biome patterns, and vegetation models can be used to assess the susceptibility of biomes to experience transitions. However, biome classification is not unique, and various classification schemes and biome maps exist. Here, we aimed to assess how the choice of biome classification schemes influences current and projected future biome patterns. Location Africa, Australia, Tropical Asia. Time period 2000–2099. Major taxa studied Tropical vegetation. Methods We used the adaptive dynamic global vegetation model version 2 (aDGVM2) to simulate vegetation in the study region. We classified vegetation into biomes using (1) a classification scheme based on the cover of functional types, (2) a cluster analysis based on the cover of functional types and (3) a cluster analysis based on trait patterns simulated by the aDGVM2. We compared the resulting biome maps to multiple observation‐based biome maps and quantified differences in projected biome changes under the RCP8.5 scenario for the different classification schemes. Results As expected, biome patterns were strongly related to the scheme used for biome classification. The highest data‐model agreement was derived for a cluster analysis using 21 simulated traits. Traits related to size were most important for classification. Considering all classification schemes, the area projected to undergo biome transitions under climate change varied between 16.5% and 32.1%. Despite this variability, different schemes consistently showed that grassland and savanna areas are most susceptible to climate change, whereas tropical forests and deserts are stable. Our results demonstrate that traits simulated by aDGVM2 are appropriate to delimit biomes. Main conclusions Studies projecting biome patterns and transitions under current and future climate should consider applying different biome classification schemes to avoid biases in such projections caused by biome classification schemes.

Topics & Concepts

BiomeVegetation (pathology)GrasslandClimate changeClassification schemeGeographyBiodiversityPhysical geographyEcologyEnvironmental scienceEcosystemBiologyComputer scienceMachine learningPathologyMedicineSpecies Distribution and Climate ChangeEcology and Vegetation Dynamics StudiesRemote Sensing in Agriculture