Ecosystem heterogeneity determines the ecological resilience of the Amazon to climate change

Levine, Naomi M.; Zhang, Ke; Longo, Marcos; Baccini, Alessandro; Phillips, Oliver L.; Lewis, Simon L.; Álvarez-Dávila, Esteban; Andrade, Ana; Brienen, Roel; Erwin, Terry L.; Feldpausch, Ted R.; Mendoza, Abel L. Monteagudo; Vargas, Percy Núñez; Prieto, A.; Silva-Espejo, Javier E.; Malhi, Yadvinder; Moorcroft, P. R.

doi:10.1073/pnas.1511344112

Cited by 188 publications

(205 citation statements)

References 47 publications

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“…Some also identify positive feedbacks and the possibility of switching states (e.g., Boers et al 2017;Wright et al 2017). Others suggest that more gradual transitions are possible (Levine et al 2016;Zemp et al 2017a). It is crucial to distinguish which theory or theories best conform to reality and the risk of climate switching.…”

Section: Instabilities and Implicationsmentioning

confidence: 99%

Forests, atmospheric water and an uncertain future: the new biology of the global water cycle

Sheil

2018

For. Ecosyst.

144

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Theory and evidence indicate that trees and other vegetation influence the atmospheric water-cycle in various ways. These influences are more important, more complex, and more poorly characterised than is widely realised. While there is little doubt that changes in tree cover will impact the water-cycle, the wider consequences remain difficult to predict as the underlying relationships and processes remain poorly characterised. Nonetheless, as forests are vulnerable to human activities, these linked aspects of the water-cycle are also at risk and the potential consequences of large scale forest loss are severe. Here, for non-specialist readers, I review our knowledge of the links between vegetation-cover and climate with a focus on forests and rain (precipitation). I highlight advances, uncertainties and research opportunities. There are significant shortcomings in our understanding of the atmospheric hydrological cycle and of its representation in climate models. A better understanding of the role of vegetation and tree-cover will reduce some of these shortcomings. I outline and illustrate various research themes where these advances may be found. These themes include the biology of evaporation, aerosols and atmospheric motion, as well as the processes that determine monsoons and diurnal precipitation cycles. A novel theory-the 'biotic pump'-suggests that evaporation and condensation can exert a major influence over atmospheric dynamics. This theory explains how high rainfall can be maintained within those continental land-masses that are sufficiently forested. Feedbacks within many of these processes can result in non-linear behaviours and the potential for dramatic changes as a result of forest loss (or gain): for example, switching from a wet to a dry local climate (or visa-versa). Much remains unknown and multiple research disciplines are needed to address this: forest scientists and other biologists have a major role to play. New ideas, methods and data offer opportunities to improve understanding. Expect surprises.

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Section: Instabilities and Implicationsmentioning

confidence: 99%

Forests, atmospheric water and an uncertain future: the new biology of the global water cycle

Sheil

2018

For. Ecosyst.

144

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“…At the global scale, watersheds are now suffering from severe perturbations due to both climate change and anthropogenic disturbances, and notable examples include the Amazon basin and the Mississippi River basin (Davidson et al, 2012;Kidder, 2006;Levine et al, 2016;Liu and Zheng, 2002). In the Amazon basin, which is the location of the world's largest rainforest, unprecedented deforestation has caused a series of changes at the local and regional scales that have involved alterations in energy and water cycles (Davidson et al, 2012).…”

Section: Introductionmentioning

confidence: 99%

“…As a representative of the capacity of a watershed to absorb and recover from perturbations or disturbances (Folke et al, 2010;Hoque et al, 2012;Randhir, 2014;Wilson and Browning, 2012), watershed resilience and associated transitions in watershed systems has becomes a critical topic in river basin conservation and management (Davidson et al, 2012). In order to understand the vulnerability and resilience of river basins in the face of change, numerous studies have strived to improve knowledge of the linkages between natural variability, drivers of change, ecosystem responses, and feedbacks within a watershed system or its subsystems; these studies have employed both tendency analysis of perturbations and watershed structure (Costa et al, 2003;Zhang et al, 2014a;Zhao et al, 2015a) and process-based model simulations (Coe et al, 2002(Coe et al, , 2011Hu et al, 2015;Levine et al, 2016). For example, Nemec et al (2014) calculated watershed resilience with nine watershed structure properties, i.e.…”

Section: Introductionmentioning

confidence: 99%

“…Hirota et al (2011) recognized forest, savanna, and treeless state as three distinct attractors and empirically reconstructed the basin of attraction through analyzing the response of the global tree abundance pattern to precipitation. Levine et al (2016) predicted the stability of the Amazon rainforest to climate change with coupled vegetation-climate models. Furthermore, Cosens and Williams (2012) analyzed resilience mechanisms in the Amudarya River basin through an agent-based model.…”

Section: Introductionmentioning

confidence: 99%

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Resilience changes in watershed systems: A new perspective to quantify long-term hydrological shifts under perturbations

Feng

Sun

et al. 2016

Journal of Hydrology

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Keywords:Critical slowing down Resilience indicator Convex model Hydrological regime shift Watershed systems s u m m a r y Natural hydrological regimes are essential to the stability of river basins. While numerous efforts have been put forth to characterize flow regime alterations driven by climate change and human activities, few approaches have been proposed to explore changes in watershed resilience. The present study attempted to introduce a systematic approach that can be used to identify the resilience change of river basins based on annual river discharge through the application of a convex model and the principle of critical slowing down. Specifically, a resilience indicator (p i ) that reflects streamflow autocorrelation at a given time was proposed to represent the temporal variation of the system resilience, and annual water discharge at representative hydrological stations located in upstream, midstream, and downstream regions of a river basin was used to reflect alterations in long-term hydrological processes and the stability of river basins. The application of this method to the Yellow River basin and Yangtze River basin indicated that the system resilience was lower in downstream regions compared to upstream regions. The Yellow River basin has suffered a decrease in resilience in its lower reaches since 1971, which extended to the middle reaches in 1987 and upper reaches in 1990. Similarly, recent observation of the resilience change in the Yangtze River basin indicated that resilience in its lower reaches has likely decreased since 2002, and this low resilience extended to the middle reaches in 2005. Overall, our study presents a new method to predict potential decreases of resilience in complex large scale watershed systems where mechanistic insight is insufficient to build reliable basin-scale hydrological, climate, ecosystem integrated models.

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“…Examples of such heterogeneity include local differences in water availability, differential responses of species to water stress and differences in soil properties (Levine et al, 2016). Examples include gallery forests, which occur in savanna landscapes where local water availability is high.…”

Section: Discussionmentioning

confidence: 99%

Resilience of tropical forest and savanna: bridging theory and observation

Staal¹

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Ecosystem heterogeneity determines the ecological resilience of the Amazon to climate change

Cited by 188 publications

References 47 publications

Forests, atmospheric water and an uncertain future: the new biology of the global water cycle

Forests, atmospheric water and an uncertain future: the new biology of the global water cycle

Resilience changes in watershed systems: A new perspective to quantify long-term hydrological shifts under perturbations

Resilience of tropical forest and savanna: bridging theory and observation

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