Published in the prestigious journal Science, the study shows how increases in aridity can alter the capacity of these ecosystems to sustain life, also limiting the provision of essential ecosystem services to more than 2 billion people living in those areas
Photos 1-3: Researchers in one of the areas investigated in the study, in Argentinian Patagonia. Photos by Juan José Gaitán, INTA (Argentina)
Photo 4: Dryland ecosystem in the Namib Desert (Namibia). Photo by Martin Handjaba
Alicante. Thursday 13 February 2020
Drylands cover about 41% of the Earth’s land surface and host one in three humans inhabiting our planet. In these areas, life is highly influenced by aridity, i.e. the balance between the amount of rainwater and the water lost by evaporation. In this sense, aridity is increasing worldwide as a result of climate change. A study conducted by the Dryland Ecology and Global Change Lab at the University of Alicante (UA) led by Fernando T. Maestre and published in Science revealed for the first time that as aridity increases, dryland ecosystems on the planet undergo a series of abrupt changes.
“In the study we found that numerous ecosystem characteristics had a non-linear response to small aridity increases. This means that there are levels at which faster, sometimes even abrupt shifts occur as a result of relatively small aridity increases. Therefore, it can be said that, when certain aridity thresholds are crossed, the ecosystem undergoes disproportionate changes and becomes even more arid”, Santiago Soliveres, Ramón y Cajal researcher at the UA and co-author of the study, explains.
Three phases of change
Three phases of change were identified by the researchers. First, when aridity levels cross values of around 0.54, “the ecosystem becomes limited by the lack of water. The vegetation changes and it becomes dominated by species adapted to drought, such as grasses and shrubs, as is already the case in many areas in the Iberian Peninsula”, UA researcher Fernando T. Maestre points out.
After these initial vegetation changes, when aridity values exceed 0.7, the soil becomes much less fertile. It loses its structure and becomes more vulnerable to erosion. Moreover, soil organisms that play essential roles in maintaining soil nutrients are radically affected, with a dominant presence of pathogens at the expense of more beneficial organisms.
Finally, beyond aridity values of 0.8, an abrupt loss of diversity and plant cover takes place. “Once this threshold is crossed, the water deficit is such that plants cannot thrive in these conditions. Biological activity is drastically reduced and life becomes conditioned by the windows of opportunity that occur during infrequent rain events. The ecosystem has become a desert”, according to Maestre.
20% of global lands affected by 2100
According to climate forecasts, more than 20% of the emerged lands of the planet may cross one or several of the aridity thresholds identified in this study by 2100. ‘Life will not disappear, but our findings suggest that these ecosystems may experience abrupt changes that will reduce their capacity to provide ecosystem services to more than 2 billion people, such as soil fertility and biomass production”, says Miguel Berdugo, the lead author of the study and a researcher at the UA Dryland Ecology and Global Change Lab until January 2020.
Minimising negative consequences
The findings of this study are of great relevance in understanding the impacts of climate change on dryland ecosystems, as they could help establish mitigation actions. “While we will not stop climate change, I believe we still can minimise its negative consequences on these ecosystems, which are essential to achieve a sustainable development”, says Maestre. “By providing information on how vegetation and soil properties change as aridity increases, and by mapping those areas most sensible to such increases, our results can be used to optimise monitoring and restoration efforts, preserve biodiversity and avoid the desertification of these ecosystems”, he adds. Ricard Solé, a co-author of the study, ICREA researcher at the Institute of Evolutionary Biology (IBE, UPF-CSIC) and lecturer at the Pompeu Fabra University, hopes that “this study will help develop potential intervention scenarios that may include the use of synthetic biology to modify ecosystems at risk”. This “terraformation“ of ecosystems is part of the ongoing collaboration between the UPF and the University of Alicante.
This unprecedented study, which provides the largest collection of data on dryland areas across several continents so far, has been conducted within the BIODESERT programme, funded under the European Research Council’s Consolidator Grants programme.
Professor of Ecology Fernando T. Maestre joined the University of Alicante in 2019 as a distinguished researcher within the Valencia Region Government’s GenT programme, which aims to attract talented expatriates back to Spain. Current director of the Dryland Ecology and Global Change Lab, devoted to understanding how dryland ecosystems work and how they are responding to environmental change, he is also a member of the Ramón Margalef Institute for Environmental Research (IMEM).
Maestre has won two ERC grants: a Starting Grant for the BIOCOM project in 2010, and a Consolidator Grant for the BIODESERT project in 2016. Moreover, he has been on the international list of Highly Cited Researchers since 2018, which recognises those researchers with multiple papers that rank in the top 1% by citations worldwide.
Berdugo, M., M. Delgado-Baquerizo, S. Soliveres, R. Hernández-Clemente, Y. Zhao, J. J. Gaitán, N. Gross, H. Saiz, V. Maire, A. Lehman, M. C. Rillig, R. V. Solé & F. T. Maestre. 2020. “Global ecosystem thresholds driven by aridity”. Science DOI: 10.1126/science.aay5958
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