Agricultural large-scale land acquisitions have been linked with enhanced deforestation and land use change. Yet the extent to which transnational agricultural large-scale land acquisitions (TALSLAs) contribute to—or merely correlate with—deforestation, and the expected biodiversity impacts of the intended land use changes across ecosystems, remains unclear. We examine 178 georeferenced TALSLA locations in 40 countries to address this gap. While forest cover within TALSLAs decreased by 17% between 2000 and 2018 and became more fragmented, the spatio-temporal patterns of deforestation varied substantially across regions. While deforestation rates within initially forested TALSLAs were 1.5 (Asia) to 2 times (Africa) higher than immediately surrounding areas, we detected no such difference in Europe and Latin America. Our findings suggest that, whereas TALSLAs may have accelerated forest loss in Asia, a different mechanism might emerge in Africa where TALSLAs target areas already experiencing elevated deforestation. Regarding biodiversity (here focused on vertebrate species), we find that nearly all (91%) studied deals will likely experience substantial losses in relative species richness (−14.1% on average within each deal)—with mixed outcomes for relative abundance—due to the intended land use transitions. We also find that 39% of TALSLAs fall at least partially within biodiversity hotspots, placing these areas at heightened risk of biodiversity loss. Taken together, these findings suggest distinct regional differences in the nature of the association between TALSLAs and forest loss and provide new evidence of TALSLAs as an emerging threat to biodiversity in the Global South.
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Abstract Several studies have shown that dust emission (vertical flux,
F ) can be considered a constant fraction (k ) of the saltating flux (horizontal flux,Q ), that is, . This coefficient of proportionality, or dust production efficiency factor, is often called the ‘k factor’ and is fundamentally related to soil properties especially soil texture. Beyond regional and global modeling applications, a practical utility ofk is for air quality regulatory agencies wherek can be used to estimateF based on only measurements ofQ , which is more easily measured in the field. Only a few studies have directly estimated thek factor from soils within potential dust sources even though dust models that represent the sandblasting process typically utilizek . The goal of this study was to compare two methods to calculatek from sandy sediments and compare those estimates with an empirical method of calculating thek factor. The first method (method 1) used the difference betweenF calculated from two sets of sediment samplers whereas the second method (method 2) used a set of aerosol monitors to measureF . We found that the range ofk values from our study are consistent with soil texture‐based estimates ofk and also have the correct order of magnitude. Thus, any of the methods described in our study are appropriate for estimation ofk for sandy soils. -
Abstract Plants with crassulacean acid metabolism (CAM) are increasing in distribution and abundance in drylands worldwide, but the underlying drivers remain unknown. We investigate the impacts of extreme drought and CO2enrichment on the competitive relationships between seedlings of
Cylindropuntia imbricata (CAM species) andBouteloua eriopoda (C4grass), which coexist in semiarid ecosystems across the Southwestern United States. Our experiments under altered water and CO2water conditions show thatC. imbricata positively responded to CO2enrichment under extreme drought conditions, whileB. eriopoda declined from drought stress and did not recover after the drought ended. Conversely, in well‐watered conditionsB. eriopoda had a strong competitive advantage onC. imbricata such that the photosynthetic rate and biomass (per individual) ofC. imbricata grown withB. eriopoda were lower relative to when growing alone. A meta‐analysis examining multiple plant families across global drylands shows a positive response of CAM photosynthesis and productivity to CO2enrichment. Collectively, our results suggest that under drought and elevated CO2concentrations, projected with climate change, the competitive advantage of plant functional groups may shift and the dominance of CAM plants may increase in semiarid ecosystems.