Early-Warning Signals of Individual Tree Mortality Based on Annual Radial Growth

Cailleret, Maxime; Dakos, Vasilis; Jansen, Steven; Robert, Elisabeth M. R.; Aakala, Tuomas; Amoroso, Mariano M.; Antos, Joe A.; Bigler, Christof; Bugmann, Harald; Caccianaga, Marco; Camarero, J. Julio; Cherubini, Paolo; Coyea, Marie R.; Čufar, Katarina; Das, Adrian J.; Davi, Hendrik; Gea‐Izquierdo, Guillermo; Gillner, Sten; Haavik, Laurel J.; Hartmann, Henrik; Hereş, Ana‐Maria; Hultine, Kevin R.; Janda, Pavel; Kane, Jeffrey M.; Kharuk, Viachelsav I.; Kitzberger, Thomas; Klein, Tamir; Levanič, Tom; Linares, Juan-Carlos; Lombardi, Fabio; Mäkinen, Harri; Mészáros, Ilona; Metsaranta, Juha M.; Oberhuber, Walter; Papadopoulos, Andreas; Petritan, Any Mary; Rohner, Brigitte; Sangüesa‐Barreda, Gabriel; Smith, Jeremy M.; Stan, Amanda B.; Stojanović, Dejan; Suarez, María Laura; Svoboda, Miroslav; Trotsiuk, Volodymyr; Villalba, Ricardo; Westwood, Alana R.; Wyckoff, P.; Martínez‐Vilalta, Jordi

doi:10.3389/fpls.2018.01964

Cited by 134 publications

(87 citation statements)

References 110 publications

(168 reference statements)

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“…Despite their ubiquity, legacy effects are highly variable across taxa (Camarero et al 2018) and can even vary within the same species due to differences in age (Gao et al 2018), site conditions such as stand density and diversity (Gazol & Camarero 2016; Bottero et al 2017), and drought characteristics such as severity and seasonal timing (Merlin et al 2015; Huang et al 2018; Kannenberg et al 2019a). Finally, legacy effects can alter demographic processes such as mortality (Berdanier & Clark 2016; Vanoni et al 2016; Cailleret et al 2017; Cailleret et al 2019), which in turn have cascading consequences for ecosystem fluxes (Anderegg et al 2016).…”

Section: Introductionmentioning

confidence: 99%

Ghosts of the past: how drought legacy effects shape forest functioning and carbon cycling

2020

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Multi-year lags in tree drought recovery, termed 'drought legacy effects', are important for understanding the impacts of drought on forest ecosystems, including carbon (C) cycle feedbacks to climate change. Despite the ubiquity of lags in drought recovery, large uncertainties remain regarding the mechanistic basis of legacy effects and their importance for the C cycle. In this review, we identify the approaches used to study legacy effects, from tree rings to whole forests. We then discuss key knowledge gaps pertaining to the causes of legacy effects, and how the various mechanisms that may contribute these lags in drought recovery could have contrasting implications for the C cycle. Furthermore, we conduct a novel data synthesis and find that legacy effects differ drastically in both size and length across the US depending on if they are identified in tree rings versus gross primary productivity. Finally, we highlight promising approaches for future research to improve our capacity to model legacy effects and predict their impact on forest health. We emphasise that a holistic view of legacy effectsfrom tissues to whole forestswill advance our understanding of legacy effects and stimulate efforts to investigate drought recovery via experimental, observational and modelling approaches.

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Section: Introductionmentioning

confidence: 99%

Ghosts of the past: how drought legacy effects shape forest functioning and carbon cycling

2020

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“…Recent evidence suggests that forest dieback may be manifested as a loss of growth resilience capacity to extreme events and the presence of negative growth trends (Camarero et al, 2015(Camarero et al, , 2018Cailleret et al, 2017). In fact, stand level negative growth trends can indicate a gradual loss in tree vigor and can be used as an early warning signal of tree vulnerability to drought (e.g., Camarero et al, 2015;Cailleret et al, 2019). When growth decline becomes widespread within a stand it can be indicative of increased forest vulnerability (e.g., Camarero et al, 2018).…”

Section: Introductionmentioning

confidence: 99%

Forecasting Forest Vulnerability to Drought in Pyrenean Silver Fir Forests Showing Dieback

Gazol

Sangüesa‐Barreda

Camarero

2020

Front. For. Glob. Change

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Forest dieback is manifested as widespread loss of tree vigor, growth decline and high mortality rates. Forest dieback is becoming increasingly frequent and extended, particularly in drought-prone regions. This is the case of the southwestern Spanish Pyrenees, where keystone species such as Silver fir reach their xeric and southern distribution limits. While dieback of this species has been widely documented in this area, we still lack methodologies to forecast the vulnerability of these forests in response to increasing drought stress so as to anticipate their potential dieback in the future. Here we study multiple features of Silver fir forests and trees to evaluate whether previous growth rates and their growth trends are valid predictors of forest dieback. Further, we validate our methodology revisiting two Silver fir sites sampled two decades ago. The defoliation degree was strongly related with radial growth, and growth trends differed between moderately to highly defoliated trees and non-defoliated trees. Forests showing dieback, i.e., those in which 25% of the sampled trees showed defoliation > 50%, were located at low elevation and received less rainfall in summer than forests showing no dieback. Trees showing high defoliation presented lower growth rates than nondefoliated trees. Moreover, we ratified that defoliation has increased considerably over the last two decades in one of the two revisited sites, but we were unable to accurately forecast growth trends in both sites, particularly in the site not showing dieback. The retrospective assessment of growth rates and trends offers valuable information on the vulnerability of Silver fir trees to drought. However, we are still far from being able to forecast the vulnerability of Silver fir forests to increasing drought. A systematic monitoring of growth across a wide tree-ring network of sites might provide valuable information to advance in this direction.

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“…This incentivizes efforts to develop and employ common methodological strategies across many sites globally to assess relationships between tree-ring-based records of growth and mortality. The representativeness of angiosperms in tree mortality studies using global databases, in particular the South American tree broadleaf species, is very poor [6,[27][28][29].…”

Section: Introductionmentioning

confidence: 99%

Radial Growth Patterns Associated with Tree Mortality in Nothofagus pumilio Forest

Rodríguez‐Catón

Villalba

Srur

et al. 2019

Forests

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Tree mortality is a key process in forest dynamics. Despite decades of effort to understand this process, many uncertainties remain. South American broadleaf species are particularly under-represented in global studies on mortality and forest dynamics. We sampled monospecific broadleaf Nothofagus pumilio forests in northern Patagonia to predict tree mortality based on stem growth. Live or dead conditions in N. pumilio trees can be predicted with high accuracy using growth rate as an explanatory variable in logistic models. In Paso Córdova (CO), Argentina, where the models were calibrated, the probability of death was a strong negative function of radial growth, particularly during the six years prior to death. In addition, negative growth trends during 30 to 45 years prior to death increased the accuracy of the models. The CO site was affected by an extreme drought during the summer 1978-1979, triggering negative trends in radial growth of many trees. Individuals showing below-average and persistent negative trends in radial growth are more likely to die than those showing high growth rates and positive growth trends in recent decades, indicating the key role of droughts in inducing mortality. The models calibrated at the CO site showed high verification skill by accurately predicting tree mortality at two independent sites 76 and 141 km away. Models based on relative growth rates showed the highest and most balanced accuracy for both live and dead individuals. Thus, the death of individuals across different N. pumilio sites was largely determined by the growth rate relative to the total size of the individuals. Our findings highlight episodic severe drought as a triggering mechanism for growth decline and eventual death for N. pumilio, similar to results found previously for several other species around the globe. In the coming decades, many forests globally will be exposed to more frequent and/or severe episodes of reduced warm-season soil moisture. Tree-ring studies such as this one can aid prediction of future changes in forest productivity, mortality, and composition. Author Contributions: R.V., M.R.-C., and A.S. planned and designed plot setup and collected samples for the research with the help of people mention in Acknowledgments; methodology, R.V., M.R.-C.; dendrochronological processing and formal analysis, M.R.-C.; resources and funding acquisition, R.V., M.R.-C., A.S., and A.P.W.; data curation, M.R.-C.; writing-original draft preparation, M.R.-C.; writing-review and editing, M.R.-C., R.V., A.S., and A.P.W.; supervision, R.V. and A.S. Funding:We are grateful for support from Consejo Nacional de Investigaciones Científicas y Técnicas for providing the postdoctoral fellowship (CONICET), Argentina and BNP-PARIBAS Foundation through THEMES Project. APW was supported by NSF awards 1602581 and 1743738.

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Early-Warning Signals of Individual Tree Mortality Based on Annual Radial Growth

Cited by 134 publications

References 110 publications

Ghosts of the past: how drought legacy effects shape forest functioning and carbon cycling

Ghosts of the past: how drought legacy effects shape forest functioning and carbon cycling

Forecasting Forest Vulnerability to Drought in Pyrenean Silver Fir Forests Showing Dieback

Radial Growth Patterns Associated with Tree Mortality in Nothofagus pumilio Forest

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