Individual tree damage dominates mortality risk factors across six tropical forests

Zuleta, Daniel; Arellano, Gabriel; Muller‐Landau, Helene C.; McMahon, Sean M.; Aguilar, Salomón; Bunyavejchewin, Sarayudh; Chang‐Yang, Chia‐Hao; Duque, Álvaro; Mitre, David; Nasardin, Musalmah; Pérez, Rolando; Sun, I‐Fang; Yao, Tze Leong; Davies, Stuart J.

doi:10.1111/nph.17832

Cited by 32 publications

(43 citation statements)

References 77 publications

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“…These trees have crowns most exposed to light, making them more susceptible to water stress caused by intense droughts or lengthening of dry seasons (Aleixo et al, 2019; Costa et al, 2010). Thus, the mortality of these trees may be caused by a combination of physiological and mechanical factors (Zuleta et al, 2021). Our results suggest that the stress generated by drought may be increasing the predisposition of trees to break just as much as it kills directly via hydraulic failure.…”

Section: Discussionmentioning

confidence: 99%

“…The likelihood and cause of tree death vary across different canopy layers (Camac et al, 2018). Competition for light is likely to impact especially trees growing in the understorey that are shaded by neighbours and are potentially close to their carbon compensation point (Camac et al, 2018; McDowell et al, 2018; Wright et al, 2010; Zuleta et al, 2021). Sub‐canopy trees may be more susceptible to death from mechanical damage generated by canopy trees' death or breakage and extreme weather events (Toledo et al, 2012; Yang et al, 2003).…”

Section: Introductionmentioning

confidence: 99%

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Climate and crown damage drive tree mortality in southern Amazonian edge forests

et al. 2022

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Tree death is a key process for our understanding of how forests are and will respond to global change. The extensive forests across the southern Amazonia edge—the driest, warmest and most fragmented of the Amazon regions—provide a window onto what the future of large parts of Amazonia may look like. Understanding tree mortality and its drivers here is essential to anticipate the process across other parts of the basin. Using 10 years of data from a widespread network of long‐term forest plots, we assessed how trees die (standing, broken or uprooted) and used generalised mixed‐effect models to explore the contribution of plot‐, species‐ and tree‐level factors to the likelihood of tree death. Most trees died from stem breakage (54%); a smaller proportion died standing (41%), while very few were uprooted (5%). The mortality rate for standing dead trees was greatest in forests subject to the most intense dry seasons. While trees with the crown more exposed to light were more prone to death from mechanical damage, trees less exposed were more susceptible to death from drought. At the species level, mortality rates were lowest for those species with the greatest wood density. At the individual tree level, physical damage to the crown via branch breakage was the strongest predictor of tree death. Synthesis. Wind‐ and water deficit‐driven disturbances are the main causes of tree death in southern Amazonia edge which is concerning considering the predicted increase in seasonality for Amazonia, especially at the edge. Tree mortality here is greater than any in other Amazonian region, thus any increase in mortality here may represent a tipping point for these forests.

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Section: Discussionmentioning

confidence: 99%

Section: Introductionmentioning

confidence: 99%

Climate and crown damage drive tree mortality in southern Amazonian edge forests

et al. 2022

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“…We used both the living length and b l to estimate the biomass of a living tree based on an allometric function that accounts for the vertical distribution of volume in the trunk vs. crown (Ver Planck & MacFarlane, 2014). Specifically, we estimated the proportion of crown volume below a given height (within the living length) and multiplied it by the relative biomass of the crown, which was set to 1/3 of the total biomass of the tree based on empirical data from 611 harvested tropical trees (Chambers et al, 2001; Duque et al, 2017), see (Zuleta et al, 2021, 2022), and Methods S3 for a full explanation. Based on estimated damage we grouped trees into five damage classes (corresponding to the damage classes used in FATES) and calculated mortality, M , for each class as

M_{d} goodbreak= ()(, \log ()(, N_{1, d}) goodbreak- \log ()(, N_{italic2})) / t,

where d is damage class, N 1 is the number of individuals alive in census 1, N 2 is the number of individuals alive in census 2 (regardless of damage class in census 2), and t is time in years between censuses.…”

Section: Methodsmentioning

confidence: 99%

“…Crown damage is an important predictor of individual tree mortality (Arellano et al, 2019; Reis et al, 2022). After light limitation, crown loss was found to have the largest impact on forest wide mortality out of 19 risk factors assessed across six tropical forests (Zuleta et al, 2021). A number of mechanisms could drive the damage‐mortality relationship.…”

Section: Introductionmentioning

confidence: 99%

Tree crown damage and its effects on forest carbon cycling in a tropical forest

Needham

Arellano

Davies

et al. 2022

Global Change Biology

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MethodsS1 Recovery algorithm Methods S2 Sensitivity analyses Methods S3 Estimates of damage class from field data Figs S1 -S12 Tables S1 -S2 Summary• Crown damage can account for over 23% of canopy biomass turnover in tropical forests and is a strong predictor of tree mortality, yet it is not typically represented in vegetation models. We incorporate crown damage into the Functionally Assembled Terrestrial Ecosystem Simulator (FATES), to evaluate how lags between damage and tree recovery or death alter demographic rates and patterns of carbon turnover.• We represent crown damage as a reduction in a tree's crown area and leaf and branch biomass, and allow associated variation in the ratio of aboveground to belowground plant tissue. We compare simulations with crown damage to simulations with equivalent instant increases in mortality and benchmark results against data from Barro Colorado Island (BCI), Panama.• In FATES, crown damage causes decreases in growth rates that match observations from BCI.Crown damage leads to increases in carbon starvation mortality in FATES, but only in configurations with high root respiration and decreases in carbon storage following damage.Crown damage also alters competitive dynamics, as plant functional types that can recover from crown damage outcompete those that cannot.• This is a first exploration of the trade-off between the additional complexity of the novel crown damage module and improved predictive capabilities. At BCI, a tropical forest that does not experience high levels of disturbance, both the crown damage simulations and simulations with equivalent increases in mortality do a reasonable job of capturing observations.• The crown damage module provides functionality for exploring dynamics in forests with more extreme disturbances such as cyclones, and for capturing the synergistic effects of disturbances that overlap in space and time.

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“…Tree stature relates to different tradeoffs between species such as the growth versus survival tradeoff (Wright et al, 2010) and the early reproduction versus annual fecundity tradeoff (Wright, 2005). Species of different size have access to different levels of light and show different tolerances to shade (Poorter et al, 2005); they have different life spans (Lieberman et al, 1985), reproductive strategies (Gilbert et al, 2006), dispersal potential (Thompson et al, 2011); and are exposed to different mortality risks (Zuleta et al, 2022). Vertical stratification in tropical forests has been studied for decades (Horn, 1971; Terborgh, 1985) and clearly has a niche or life‐strategy component, with some species being reported as understory species and other species as typical canopy species.…”

Section: Introductionmentioning

confidence: 99%

Analyses of three‐dimensional species associations reveal departures from neutrality in a tropical forest

Zambrano

Arellano

Swenson

et al. 2022

Ecology

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The study of community spatial structure is central to understanding diversity patterns over space and species co‐occurrence at local scales. Although most analytical approaches consider horizontal and vertical dimensions separately, in this study we introduce a three‐dimensional spatial analysis that simultaneously includes horizontal and vertical species associations. Using tree census data (2000–2016) and allometries from the Luquillo forest plot in Puerto Rico, we show that spatial organization becomes less random over time as the forest recovered from land‐use legacy effects and hurricane disturbance. Tree species vertical segregation is predominant in the forest with almost all species that co‐occur in the horizontal plane avoiding each other in the vertical dimension. Horizontal segregation is less common than vertical, whereas three‐dimensional aggregation (a proxy for direct tree competition) is the least frequent type of spatial association. Furthermore, dominant species are involved in more non‐random spatial associations, implying that species co‐occurrence is facilitated by species segregation in space. This novel three‐dimensional analysis allowed us to identify and quantify tree species spatial distributions, how interspecific competition was reduced through forest structure, and how it changed over time after disturbance, in ways not detectable from two‐dimensional analyses alone.

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Individual tree damage dominates mortality risk factors across six tropical forests

Cited by 32 publications

References 77 publications

Climate and crown damage drive tree mortality in southern Amazonian edge forests

Climate and crown damage drive tree mortality in southern Amazonian edge forests

Tree crown damage and its effects on forest carbon cycling in a tropical forest

Analyses of three‐dimensional species associations reveal departures from neutrality in a tropical forest

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