Terrestrial Vertebrate Biodiversity Loss under Future Global Land Use Change Scenarios

Abhishek Chaudhary,Arne Mooers

doi:10.3390/su10082764

Abstract

Efficient forward-looking mitigation measures are needed to halt the global biodiversity decline. These require spatially explicit scenarios of expected changes in multiple indicators of biodiversity under future socio-economic and environmental conditions. Here, we link six future (2050 and 2100) global gridded maps (0.25° × 0.25° resolution) available from the land use harmonization (LUH) database, representing alternative concentration pathways (RCP) and shared socio-economic pathways (SSPs), with the countryside species–area relationship model to project the future land use change driven rates of species extinctions and phylogenetic diversity loss (in million years) for mammals, birds, and amphibians in each of the 804 terrestrial ecoregions and 176 countries and compare them with the current (1900–2015) and past (850–1900) rates of biodiversity loss. Future land-use changes are projected to commit an additional 209–818 endemic species and 1190–4402 million years of evolutionary history to extinction by 2100 depending upon the scenario. These estimates are driven by land use change only and would likely be higher once the direct effects of climate change on species are included. Among the three taxa, highest diversity loss is projected for amphibians. We found that the most aggressive climate mitigation scenario (RCP2.6 SSP-1), representing a world shifting towards a radically more sustainable path, including increasing crop yields, reduced meat production, and reduced tropical deforestation coupled with high trade, projects the lowest land use change driven global biodiversity loss. The results show that hotspots of future biodiversity loss differ depending upon the scenario, taxon, and metric considered. Future extinctions could potentially be reduced if habitat preservation is incorporated into national development plans, especially for biodiverse, low-income countries such as Indonesia, Madagascar, Tanzania, Philippines, and The Democratic Republic of Congo that are otherwise projected to suffer a high number of land use change driven extinctions under all scenarios.

Highlights

The rapid decline in global biodiversity likely has major consequences for ecosystem functioning and human wellbeing [1], and international agreements such as the United Nations sustainable development goals (SDGs; [2]) and the Convention on Biological Diversity Aichi targets [3] commit to reducing these losses
We found that the most aggressive climate mitigation scenario (RCP2.6 shared socio-economic pathways (SSPs)-1), representing a world shifting towards a radically more sustainable path, including increasing crop yields, reduced meat production, and reduced tropical deforestation coupled with high trade, projects the lowest land use change driven global biodiversity loss
We found that the most aggressive climate change mitigation scenario coupled with a sustainable socio-economic trajectory (RCP2.6 SSP-1) results in the least land use change, and projects the lowest global biodiversity loss in future

Summary

Introduction

The rapid decline in global biodiversity likely has major consequences for ecosystem functioning and human wellbeing [1], and international agreements such as the United Nations sustainable development goals (SDGs; [2]) and the Convention on Biological Diversity Aichi targets [3] commit to reducing these losses. The Intergovernmental Platform on Biodiversity and Ecosystem Services (IPBES) has identified that reporting past, present, and future trends of biodiversity at global and regional levels and development of scenarios is key to help decision makers evaluate different policy options [4,5]. To meet the call of the IPBES, and to project a more accurate picture of the future of biodiversity, we need advancements in both land use projections and in models that translate these projections onto changes in different aspects of biodiversity (e.g., taxonomic, genetic, functional).

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Results

Conclusion