Habitat percolation transition undermines sustainability in social‐ecological agricultural systems

Abstract. Droughts continue to affect ecosystems, communities, and entire economies. Agriculture bears much of the impact, and in many countries it is the most heavily affected sector. Over the past decades, efforts have been made to assess drought risk at different spatial scales. Here, we present for the first time an integrated assessment of drought risk for both irrigated and rain-fed agricultural systems at the global scale. Composite hazard indicators were calculated for irrigated and rain-fed systems separately using different drought indices based on historical climate conditions (1980–2016). Exposure was analyzed for irrigated and non-irrigated crops. Vulnerability was assessed through a social-ecological systems perspective, using social-ecological susceptibility and lack of coping capacity indicators that were weighted by drought experts from around the world. The analysis shows that drought risk of rain-fed and irrigated agricultural systems displays heterogeneous pattern at the global level with higher risk for southeastern Europe, as well as northern and southern Africa. By providing information on the drivers and spatial patterns of drought risk in all dimensions of hazard, exposure, and vulnerability, the presented analysis can support the identification of tailored measures to reduce drought risk and increase the resilience of agricultural systems.

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Using the Concepts of Resilience, Vulnerability and Adaptability for the Assessment and Analysis of Agricultural Systems

Change and Adaptation in Socio-Ecological Systems ◽

10.2478/cass-2014-0001 ◽

2014 ◽

Vol 1 (1) ◽

Cited By ~ 7

Author(s):

Daniel Callo-Concha ◽

Frank Ewert

Keyword(s):

Ecological Systems ◽

Agricultural Systems ◽

Social Ecological Systems ◽

Social Ecological ◽

Operational Application ◽

Individual Concepts ◽

Operational Criteria ◽

The Individual ◽

Operational Integration ◽

Operational Aspects

AbstractResilience, vulnerability and adaptability have emerged as dominant concepts in the study of disturbance and change of social-ecological systems. We analyze the conceptual, methodological and operational aspects in using these concepts for the assessment and analysis of agricultural systems and try to identify differences and possible overlaps between them. The analysis is performed considering a number of published studies on agricultural systems over a wide geographical range where these concepts have been applied. Our results show a clear conceptual overlap and often the exchangeable use of the concepts. Furthermore, the driving methodological and operational criteria for their application could not be separated unambiguously. It was, thus, difficult to identify guiding principles for the operational application of the individual concepts. We stress that the operationalization of these concepts requires consistency in the approaches and protocols to ensure their coherent use. We also argue that the conceptual and operational integration of resilience, vulnerability and adaptability would perhaps lead to a more complete portrayal of the behavior of agricultural systems in changing situations. But this requires more research including the development of operational protocols for which the premises of complexity, participation and functionality seem key.

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Habitat percolation transition undermines sustainability in social-ecological agricultural systems

10.22541/au.162376987.78461491/v1 ◽

2021 ◽

Author(s):

Diego Bengochea Paz ◽

Kirsten Henderson ◽

Michel Loreau

Keyword(s):

Population Size ◽

Habitat Loss ◽

Human Population ◽

Agricultural Landscape ◽

Agricultural Land ◽

Agricultural Landscapes ◽

Agricultural Expansion ◽

Percolation Transition ◽

Effective Measure ◽

Social Ecological

Steady increases in human population size and resource consumption levels are driving rampant agricultural expansion and intensification in some of the world’s most pristine ecosystems. Habitat loss caused by agriculture puts the integrity of ecosystems at risk, and as a consequence, threatens the persistence of human societies that rely on ecosystem services to produce resources. Here we develop a spatially explicit model describing the coupled dynamics of an agricultural landscape and human population size to study the effect of different land-use management strategies, defined by the levels of agricultural clustering and intensification, on the sustainability of the social-ecological system. We show how gradual agricultural expansion can cause natural habitat to undergo a percolation transition leading to abrupt habitat fragmentation that feedbacks on human’s decision making, causing faster agricultural expansion and aggravating habitat loss and fragmentation. We found that agricultural intensification to spare land from conversion is a successful strategy only in highly natural landscapes and that clustering agricultural land is the most effective measure to preserve landscape connectivity and avoid severe fragmentation. Our work highlights the importance of preserving large connected natural fragments in agricultural landscapes to enhance sustainability.

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Habitat percolation transition undermines sustainability in social-ecological agricultural systems

10.1101/2021.06.07.447347 ◽

2021 ◽

Author(s):

Diego Bengochea Paz ◽

Kirsten Henderson ◽

Michel Loreau

Keyword(s):

Population Size ◽

Human Population ◽

Agricultural Landscape ◽

Agricultural Land ◽

Natural Habitat ◽

Agricultural Expansion ◽

Percolation Transition ◽

Effective Measure ◽

Landscape Degradation ◽

Social Ecological

Steady increases in human population size and resource consumption are driving rampant agricultural expansion and intensification. Habitat loss caused by agriculture puts the integrity of ecosystems at risk, and threatens the persistence of human societies that rely on ecosystem services. We develop a spatially explicit model describing the coupled dynamics of an agricultural landscape and human population size to study the effect of different land-use management strategies, defined by agricultural clustering and intensification, on the sustainability of the social-ecological system. We show how agricultural expansion can cause natural habitat to undergo a percolation transition leading to abrupt habitat fragmentation that feedbacks on human's decision making, aggravating landscape degradation. We found that agricultural intensification to spare land from conversion is a successful strategy only in highly natural landscapes, and that clustering agricultural land is the most effective measure to preserve large connected natural fragments, avoid severe fragmentation, and thus, enhance sustainability.

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