Your search keyword '"McMahon, Sean"' showing total 16 results

1. Damage to living trees contributes to almost half of the biomass losses in tropical forests.

Author

Zuleta D, Arellano G, McMahon SM, Aguilar S, Bunyavejchewin S, Castaño N, Chang-Yang CH, Duque A, Mitre D, Nasardin M, Pérez R, Sun IF, Yao TL, Valencia R, Krishna Moorthy SM, Verbeeck H, and Davies SJ

Subjects

Biomass, Forests, Carbon, Trees, Tropical Climate

Abstract

Accurate estimates of forest biomass stocks and fluxes are needed to quantify global carbon budgets and assess the response of forests to climate change. However, most forest inventories consider tree mortality as the only aboveground biomass (AGB) loss without accounting for losses via damage to living trees: branchfall, trunk breakage, and wood decay. Here, we use ~151,000 annual records of tree survival and structural completeness to compare AGB loss via damage to living trees to total AGB loss (mortality + damage) in seven tropical forests widely distributed across environmental conditions. We find that 42% (3.62 Mg ha -1  year -1 ; 95% confidence interval [CI] 2.36-5.25) of total AGB loss (8.72 Mg ha -1  year -1 ; CI 5.57-12.86) is due to damage to living trees. Total AGB loss was highly variable among forests, but these differences were mainly caused by site variability in damage-related AGB losses rather than by mortality-related AGB losses. We show that conventional forest inventories overestimate stand-level AGB stocks by 4% (1%-17% range across forests) because assume structurally complete trees, underestimate total AGB loss by 29% (6%-57% range across forests) due to overlooked damage-related AGB losses, and overestimate AGB loss via mortality by 22% (7%-80% range across forests) because of the assumption that trees are undamaged before dying. Our results indicate that forest carbon fluxes are higher than previously thought. Damage on living trees is an underappreciated component of the forest carbon cycle that is likely to become even more important as the frequency and severity of forest disturbances increase., (© 2023 John Wiley & Sons Ltd.)

Published

2023

2. Tropical tree mortality has increased with rising atmospheric water stress.

Author

Bauman D, Fortunel C, Delhaye G, Malhi Y, Cernusak LA, Bentley LP, Rifai SW, Aguirre-Gutiérrez J, Menor IO, Phillips OL, McNellis BE, Bradford M, Laurance SGW, Hutchinson MF, Dempsey R, Santos-Andrade PE, Ninantay-Rivera HR, Chambi Paucar JR, and McMahon SM

Subjects

Acclimatization, Australia, Biomass, Carbon metabolism, Carbon Sequestration, Dehydration, Global Warming statistics & numerical data, History, 20th Century, History, 21st Century, Humidity, Population Density, Risk, Time Factors, Atmosphere chemistry, Stress, Physiological, Trees classification, Trees growth & development, Trees metabolism, Tropical Climate, Water analysis, Water metabolism

Abstract

Evidence exists that tree mortality is accelerating in some regions of the tropics 1,2 , with profound consequences for the future of the tropical carbon sink and the global anthropogenic carbon budget left to limit peak global warming below 2 °C. However, the mechanisms that may be driving such mortality changes and whether particular species are especially vulnerable remain unclear 3-8 . Here we analyse a 49-year record of tree dynamics from 24 old-growth forest plots encompassing a broad climatic gradient across the Australian moist tropics and find that annual tree mortality risk has, on average, doubled across all plots and species over the last 35 years, indicating a potential halving in life expectancy and carbon residence time. Associated losses in biomass were not offset by gains from growth and recruitment. Plots in less moist local climates presented higher average mortality risk, but local mean climate did not predict the pace of temporal increase in mortality risk. Species varied in the trajectories of their mortality risk, with the highest average risk found nearer to the upper end of the atmospheric vapour pressure deficit niches of species. A long-term increase in vapour pressure deficit was evident across the region, suggesting that thresholds involving atmospheric water stress, driven by global warming, may be a primary cause of increasing tree mortality in moist tropical forests., (© 2022. The Author(s), under exclusive licence to Springer Nature Limited.)

Published

2022

3. Comparative transcriptomics of tropical woody plants supports fast and furious strategy along the leaf economics spectrum in lianas.

Author

Sezen UU, Worthy SJ, Umaña MN, Davies SJ, McMahon SM, and Swenson NG

Subjects

Forests, Plant Leaves genetics, Plant Leaves metabolism, Plants metabolism, Transcriptome, Trees physiology, Tropical Climate

Abstract

Lianas, climbing woody plants, influence the structure and function of tropical forests. Climbing traits have evolved multiple times, including ancestral groups such as gymnosperms and pteridophytes, but the genetic basis of the liana strategy is largely unknown. Here, we use a comparative transcriptomic approach for 47 tropical plant species, including ten lianas of diverse taxonomic origins, to identify genes that are consistently expressed or downregulated only in lianas. Our comparative analysis of full-length transcripts enabled the identification of a core interactomic network common to lianas. Sets of transcripts identified from our analysis reveal features related to functional traits pertinent to leaf economics spectrum in lianas, include upregulation of genes controlling epidermal cuticular properties, cell wall remodeling, carbon concentrating mechanism, cell cycle progression, DNA repair and a large suit of downregulated transcription factors and enzymes involved in ABA-mediated stress response as well as lignin and suberin synthesis. All together, these genes are known to be significant in shaping plant morphologies through responses such as gravitropism, phyllotaxy and shade avoidance., Competing Interests: Competing interests The authors declare no competing or financial interests., (© 2022. Published by The Company of Biologists Ltd.)

Published

2022

4. Distribution of biomass dynamics in relation to tree size in forests across the world.

Author

Piponiot C, Anderson-Teixeira KJ, Davies SJ, Allen D, Bourg NA, Burslem DFRP, Cárdenas D, Chang-Yang CH, Chuyong G, Cordell S, Dattaraja HS, Duque Á, Ediriweera S, Ewango C, Ezedin Z, Filip J, Giardina CP, Howe R, Hsieh CF, Hubbell SP, Inman-Narahari FM, Itoh A, Janík D, Kenfack D, Král K, Lutz JA, Makana JR, McMahon SM, McShea W, Mi X, Bt Mohamad M, Novotný V, O'Brien MJ, Ostertag R, Parker G, Pérez R, Ren H, Reynolds G, Md Sabri MD, Sack L, Shringi A, Su SH, Sukumar R, Sun IF, Suresh HS, Thomas DW, Thompson J, Uriarte M, Vandermeer J, Wang Y, Ware IM, Weiblen GD, Whitfeld TJS, Wolf A, Yao TL, Yu M, Yuan Z, Zimmerman JK, Zuleta D, and Muller-Landau HC

Subjects

Biomass, Temperature, Wood, Carbon, Tropical Climate

Abstract

Tree size shapes forest carbon dynamics and determines how trees interact with their environment, including a changing climate. Here, we conduct the first global analysis of among-site differences in how aboveground biomass stocks and fluxes are distributed with tree size. We analyzed repeat tree censuses from 25 large-scale (4-52 ha) forest plots spanning a broad climatic range over five continents to characterize how aboveground biomass, woody productivity, and woody mortality vary with tree diameter. We examined how the median, dispersion, and skewness of these size-related distributions vary with mean annual temperature and precipitation. In warmer forests, aboveground biomass, woody productivity, and woody mortality were more broadly distributed with respect to tree size. In warmer and wetter forests, aboveground biomass and woody productivity were more right skewed, with a long tail towards large trees. Small trees (1-10 cm diameter) contributed more to productivity and mortality than to biomass, highlighting the importance of including these trees in analyses of forest dynamics. Our findings provide an improved characterization of climate-driven forest differences in the size structure of aboveground biomass and dynamics of that biomass, as well as refined benchmarks for capturing climate influences in vegetation demographic models., (© 2022 The Authors. New Phytologist © 2022 New Phytologist Foundation.)

Published

2022

5. Demographic composition, not demographic diversity, predicts biomass and turnover across temperate and tropical forests.

Author

Needham JF, Johnson DJ, Anderson-Teixeira KJ, Bourg N, Bunyavejchewin S, Butt N, Cao M, Cárdenas D, Chang-Yang CH, Chen YY, Chuyong G, Dattaraja HS, Davies SJ, Duque A, Ewango CEN, Fernando ES, Fisher R, Fletcher CD, Foster R, Hao Z, Hart T, Hsieh CF, Hubbell SP, Itoh A, Kenfack D, Koven CD, Larson AJ, Lutz JA, McShea W, Makana JR, Malhi Y, Marthews T, Bt Mohamad M, Morecroft MD, Norden N, Parker G, Shringi A, Sukumar R, Suresh HS, Sun IF, Tan S, Thomas DW, Thompson J, Uriarte M, Valencia R, Yao TL, Yap SL, Yuan Z, Yuehua H, Zimmerman JK, Zuleta D, and McMahon SM

Subjects

Biomass, Demography, Ecosystem, Climate Change, Tropical Climate

Abstract

The growth and survival of individual trees determine the physical structure of a forest with important consequences for forest function. However, given the diversity of tree species and forest biomes, quantifying the multitude of demographic strategies within and across forests and the way that they translate into forest structure and function remains a significant challenge. Here, we quantify the demographic rates of 1961 tree species from temperate and tropical forests and evaluate how demographic diversity (DD) and demographic composition (DC) differ across forests, and how these differences in demography relate to species richness, aboveground biomass (AGB), and carbon residence time. We find wide variation in DD and DC across forest plots, patterns that are not explained by species richness or climate variables alone. There is no evidence that DD has an effect on either AGB or carbon residence time. Rather, the DC of forests, specifically the relative abundance of large statured species, predicted both biomass and carbon residence time. Our results demonstrate the distinct DCs of globally distributed forests, reflecting biogeography, recent history, and current plot conditions. Linking the DC of forests to resilience or vulnerability to climate change, will improve the precision and accuracy of predictions of future forest composition, structure, and function., (© 2022 John Wiley & Sons Ltd.)

Published

2022

6. Tropical tree growth sensitivity to climate is driven by species intrinsic growth rate and leaf traits.

Author

Bauman D, Fortunel C, Cernusak LA, Bentley LP, McMahon SM, Rifai SW, Aguirre-Gutiérrez J, Oliveras I, Bradford M, Laurance SGW, Delhaye G, Hutchinson MF, Dempsey R, McNellis BE, Santos-Andrade PE, Ninantay-Rivera HR, Chambi Paucar JR, Phillips OL, and Malhi Y

Subjects

Climate Change, Forests, Plant Leaves, Trees, Tropical Climate

Abstract

A better understanding of how climate affects growth in tree species is essential for improved predictions of forest dynamics under climate change. Long-term climate averages (mean climate) drive spatial variations in species' baseline growth rates, whereas deviations from these averages over time (anomalies) can create growth variation around the local baseline. However, the rarity of long-term tree census data spanning climatic gradients has so far limited our understanding of their respective role, especially in tropical systems. Furthermore, tree growth sensitivity to climate is likely to vary widely among species, and the ecological strategies underlying these differences remain poorly understood. Here, we utilize an exceptional dataset of 49 years of growth data for 509 tree species across 23 tropical rainforest plots along a climatic gradient to examine how multiannual tree growth responds to both climate means and anomalies, and how species' functional traits mediate these growth responses to climate. We show that anomalous increases in atmospheric evaporative demand and solar radiation consistently reduced tree growth. Drier forests and fast-growing species were more sensitive to water stress anomalies. In addition, species traits related to water use and photosynthesis partly explained differences in growth sensitivity to both climate means and anomalies. Our study demonstrates that both climate means and anomalies shape tree growth in tropical forests and that species traits can provide insights into understanding these demographic responses to climate change, offering a promising way forward to forecast tropical forest dynamics under different climate trajectories., (© 2021 The Authors. Global Change Biology published by John Wiley & Sons Ltd.)

Published

2022

7. Individual tree damage dominates mortality risk factors across six tropical forests.

Author

Zuleta D, Arellano G, Muller-Landau HC, McMahon SM, Aguilar S, Bunyavejchewin S, Cárdenas D, Chang-Yang CH, Duque A, Mitre D, Nasardin M, Pérez R, Sun IF, Yao TL, and Davies SJ

Subjects

Forests, Risk Factors, Trees physiology, Tropical Climate

Abstract

The relative importance of tree mortality risk factors remains unknown, especially in diverse tropical forests where species may vary widely in their responses to particular conditions. We present a new framework for quantifying the importance of mortality risk factors and apply it to compare 19 risks on 31 203 trees (1977 species) in 14 one-year periods in six tropical forests. We defined a condition as a risk factor for a species if it was associated with at least a doubling of mortality rate in univariate analyses. For each risk, we estimated prevalence (frequency), lethality (difference in mortality between trees with and without the risk) and impact ('excess mortality' associated with the risk, relative to stand-level mortality). The most impactful risk factors were light limitation and crown/trunk loss; the most prevalent were light limitation and small size; the most lethal were leaf damage and wounds. Modes of death (standing, broken and uprooted) had limited links with previous conditions and mortality risk factors. We provide the first ranking of importance of tree-level mortality risk factors in tropical forests. Future research should focus on the links between these risks, their climatic drivers and the physiological processes to enable mechanistic predictions of future tree mortality., (© 2021 The Authors. New Phytologist © 2021 New Phytologist Foundation.)

Published

2022

8. The interspecific growth-mortality trade-off is not a general framework for tropical forest community structure.

Author

Russo SE, McMahon SM, Detto M, Ledder G, Wright SJ, Condit RS, Davies SJ, Ashton PS, Bunyavejchewin S, Chang-Yang CH, Ediriweera S, Ewango CEN, Fletcher C, Foster RB, Gunatilleke CVS, Gunatilleke IAUN, Hart T, Hsieh CF, Hubbell SP, Itoh A, Kassim AR, Leong YT, Lin YC, Makana JR, Mohamad MB, Ong P, Sugiyama A, Sun IF, Tan S, Thompson J, Yamakura T, Yap SL, and Zimmerman JK

Subjects

Species Specificity, Trees, Forests, Tropical Climate

Abstract

Resource allocation within trees is a zero-sum game. Unavoidable trade-offs dictate that allocation to growth-promoting functions curtails other functions, generating a gradient of investment in growth versus survival along which tree species align, known as the interspecific growth-mortality trade-off. This paradigm is widely accepted but not well established. Using demographic data for 1,111 tree species across ten tropical forests, we tested the generality of the growth-mortality trade-off and evaluated its underlying drivers using two species-specific parameters describing resource allocation strategies: tolerance of resource limitation and responsiveness of allocation to resource access. Globally, a canonical growth-mortality trade-off emerged, but the trade-off was strongly observed only in less disturbance-prone forests, which contained diverse resource allocation strategies. Only half of disturbance-prone forests, which lacked tolerant species, exhibited the trade-off. Supported by a theoretical model, our findings raise questions about whether the growth-mortality trade-off is a universally applicable organizing framework for understanding tropical forest community structure.

Published

2021

9. Comparative foliar metabolomics of a tropical and a temperate forest community.

Author

Sedio BE, Parker JD, McMahon SM, and Wright SJ

Subjects

Panama, Phylogeny, Plants classification, Metabolomics, Tropical Climate

Abstract

Plant enemies that attack chemically similar host species are thought to mediate competitive exclusion of chemically similar plants and select for chemical divergence among closely related species. This hypothesis predicts that plant defenses should diverge rapidly, minimizing phylogenetic signal. To evaluate this prediction, we quantified metabolomic similarity for 203 tree species that represent >89% of all individuals in large forest plots in Maryland and Panama. We constructed molecular networks based on mass spectrometry of all 203 species, quantified metabolomic similarity for all pairwise combinations of species, and used phylogenetically independent contrasts to evaluate how pairwise metabolomic similarity varies phylogenetically. Leaf metabolomes exhibited clear phylogenetic signal for the temperate plot, which is inconsistent with the prediction. In contrast, leaf metabolomes lacked phylogenetic signal for the tropical plot, with particularly low metabolomic similarity among congeners. In addition, community-wide variation in metabolomes was much greater for the tropical community, with single tropical genera supporting greater metabolomic variation than the entire temperate community. Our results are consistent with the hypothesis that stronger plant-enemy interactions lead to more rapid divergence and greater metabolomic variation in tropical than temperate plants. Additional community-level foliar metabolomes will be required from tropical and temperate forests to evaluate this hypothesis., (© 2018 by the Ecological Society of America.)

Published

2018

10. Isoprene emission structures tropical tree biogeography and community assembly responses to climate.

Author

Taylor TC, McMahon SM, Smith MN, Boyle B, Violle C, van Haren J, Simova I, Meir P, Ferreira LV, de Camargo PB, da Costa ACL, Enquist BJ, and Saleska SR

Subjects

Forests, Time Factors, Butadienes analysis, Climate Change, Hemiterpenes analysis, Phylogeny, Trees physiology, Tropical Climate

Abstract

The prediction of vegetation responses to climate requires a knowledge of how climate-sensitive plant traits mediate not only the responses of individual plants, but also shifts in the species and functional compositions of whole communities. The emission of isoprene gas - a trait shared by one-third of tree species - is known to protect leaf biochemistry under climatic stress. Here, we test the hypothesis that isoprene emission shapes tree species compositions in tropical forests by enhancing the tolerance of emitting trees to heat and drought. Using forest inventory data, we estimated the proportional abundance of isoprene-emitting trees (pIE) at 103 lowland tropical sites. We also quantified the temporal composition shifts in three tropical forests - two natural and one artificial - subjected to either anomalous warming or drought. Across the landscape, pIE increased with site mean annual temperature, but decreased with dry season length. Through time, pIE strongly increased under high temperatures, and moderately increased following drought. Our analysis shows that isoprene emission is a key plant trait determining species responses to climate. For species adapted to seasonal dry periods, isoprene emission may tradeoff with alternative strategies, such as leaf deciduousness. Community selection for isoprene-emitting species is a potential mechanism for enhanced forest resilience to climatic change., (© 2018 The Authors. New Phytologist © 2018 New Phytologist Trust.)

Published

2018

11. Climate sensitive size-dependent survival in tropical trees.

Author

Johnson DJ, Needham J, Xu C, Massoud EC, Davies SJ, Anderson-Teixeira KJ, Bunyavejchewin S, Chambers JQ, Chang-Yang CH, Chiang JM, Chuyong GB, Condit R, Cordell S, Fletcher C, Giardina CP, Giambelluca TW, Gunatilleke N, Gunatilleke S, Hsieh CF, Hubbell S, Inman-Narahari F, Kassim AR, Katabuchi M, Kenfack D, Litton CM, Lum S, Mohamad M, Nasardin M, Ong PS, Ostertag R, Sack L, Swenson NG, Sun IF, Tan S, Thomas DW, Thompson J, Umaña MN, Uriarte M, Valencia R, Yap S, Zimmerman J, McDowell NG, and McMahon SM

Subjects

Biomass, Carbon, Plant Leaves, Seeds, Temperature, Water, Trees, Tropical Climate

Abstract

Survival rates of large trees determine forest biomass dynamics. Survival rates of small trees have been linked to mechanisms that maintain biodiversity across tropical forests. How species survival rates change with size offers insight into the links between biodiversity and ecosystem function across tropical forests. We tested patterns of size-dependent tree survival across the tropics using data from 1,781 species and over 2 million individuals to assess whether tropical forests can be characterized by size-dependent life-history survival strategies. We found that species were classifiable into four 'survival modes' that explain life-history variation that shapes carbon cycling and the relative abundance within forests. Frequently collected functional traits, such as wood density, leaf mass per area and seed mass, were not generally predictive of the survival modes of species. Mean annual temperature and cumulative water deficit predicted the proportion of biomass of survival modes, indicating important links between evolutionary strategies, climate and carbon cycling. The application of survival modes in demographic simulations predicted biomass change across forest sites. Our results reveal globally identifiable size-dependent survival strategies that differ across diverse systems in a consistent way. The abundance of survival modes and interaction with climate ultimately determine forest structure, carbon storage in biomass and future forest trajectories.

Published

2018

12. Drivers and mechanisms of tree mortality in moist tropical forests.

Author

McDowell N, Allen CD, Anderson-Teixeira K, Brando P, Brienen R, Chambers J, Christoffersen B, Davies S, Doughty C, Duque A, Espirito-Santo F, Fisher R, Fontes CG, Galbraith D, Goodsman D, Grossiord C, Hartmann H, Holm J, Johnson DJ, Kassim AR, Keller M, Koven C, Kueppers L, Kumagai T, Malhi Y, McMahon SM, Mencuccini M, Meir P, Moorcroft P, Muller-Landau HC, Phillips OL, Powell T, Sierra CA, Sperry J, Warren J, Xu C, and Xu X

Subjects

Carbon Dioxide metabolism, Models, Theoretical, Forests, Humidity, Trees physiology, Tropical Climate

Abstract

Tree mortality rates appear to be increasing in moist tropical forests (MTFs) with significant carbon cycle consequences. Here, we review the state of knowledge regarding MTF tree mortality, create a conceptual framework with testable hypotheses regarding the drivers, mechanisms and interactions that may underlie increasing MTF mortality rates, and identify the next steps for improved understanding and reduced prediction. Increasing mortality rates are associated with rising temperature and vapor pressure deficit, liana abundance, drought, wind events, fire and, possibly, CO 2 fertilization-induced increases in stand thinning or acceleration of trees reaching larger, more vulnerable heights. The majority of these mortality drivers may kill trees in part through carbon starvation and hydraulic failure. The relative importance of each driver is unknown. High species diversity may buffer MTFs against large-scale mortality events, but recent and expected trends in mortality drivers give reason for concern regarding increasing mortality within MTFs. Models of tropical tree mortality are advancing the representation of hydraulics, carbon and demography, but require more empirical knowledge regarding the most common drivers and their subsequent mechanisms. We outline critical datasets and model developments required to test hypotheses regarding the underlying causes of increasing MTF mortality rates, and improve prediction of future mortality under climate change., (No claim to original US government works New Phytologist © 2018 New Phytologist Trust.)

Published

2018

13. Inferring forest fate from demographic data: from vital rates to population dynamic models.

Author

Needham J, Merow C, Chang-Yang CH, Caswell H, and McMahon SM

Subjects

Demography, Models, Biological, Panama, Population Dynamics, Species Specificity, Forests, Trees growth & development, Tropical Climate

Abstract

As population-level patterns of interest in forests emerge from individual vital rates, modelling forest dynamics requires making the link between the scales at which data are collected (individual stems) and the scales at which questions are asked (e.g. populations and communities). Structured population models (e.g. integral projection models (IPMs)) are useful tools for linking vital rates to population dynamics. However, the application of such models to forest trees remains challenging owing to features of tree life cycles, such as slow growth, long lifespan and lack of data on crucial ontogenic stages. We developed a survival model that accounts for size-dependent mortality and a growth model that characterizes individual heterogeneity. We integrated vital rate models into two types of population model; an analytically tractable form of IPM and an individual-based model (IBM) that is applied with stochastic simulations. We calculated longevities, passage times to, and occupancy time in, different life cycle stages, important metrics for understanding how demographic rates translate into patterns of forest turnover and carbon residence times. Here, we illustrate the methods for three tropical forest species with varying life-forms. Population dynamics from IPMs and IBMs matched a 34 year time series of data (albeit a snapshot of the life cycle for canopy trees) and highlight differences in life-history strategies between species. Specifically, the greater variation in growth rates within the two canopy species suggests an ability to respond to available resources, which in turn manifests as faster passage times and greater occupancy times in larger size classes. The framework presented here offers a novel and accessible approach to modelling the population dynamics of forest trees., (© 2018 The Authors.)

Published

2018

14. Ecological and environmental factors constrain sprouting ability in tropical trees.

Author

Salk CF and McMahon SM

Subjects

Panama, Population Dynamics, Regeneration, Species Specificity, Trees physiology, Ecosystem, Trees growth & development, Tropical Climate

Abstract

Most theories of forest biodiversity focus on the role of seed dispersal and seedling establishment in forest regeneration. In many ecosystems, however, sprouting by damaged stems determines which species occupies a site. Damaged trees can quickly recover from disturbance and out-compete seedlings. Links among species' traits, environmental conditions and sprouting could offer insight into species' resilience to changes in climate, land use, and disturbance. Using data for 25 Neotropical tree species at two sites with contrasting rainfall and soil, we tested hypotheses on how four functional traits (seed mass, leaf mass per area, wood density and nitrogen fixation) influence species' sprouting responses to disturbance and how these relationships are mediated by a tree's environmental context. Most species sprouted in response to cutting, and many species' sprouting rates differed significantly between sites. Individual traits showed no direct correlation with sprouting. However, interactions among traits and site variables did affect sprouting rates. Many species showed increased sprouting in the higher-quality site. Most nitrogen-fixing species showed the opposite trend, sprouting more frequently where resources are scarce. This study highlights the use of functional traits as a proxy for life histories, and demonstrates the importance of environmental effects on demography.

Published

2011

15. Latitudinal patterns in stabilizing density dependence of forest communities.

Author

Holík, Jan, Howe, Robert, Hubbell, Stephen, Itoh, Akira, Johnson, Daniel, Kenfack, David, Král, Kamil, Larson, Andrew, Lutz, James, Makana, Jean-Remy, Malhi, Yadvinder, McMahon, Sean, McShea, William, Mohamad, Mohizah, Nasardin, Musalmah, Nathalang, Anuttara, Norden, Natalia, Oliveira, Alexandre, Parmigiani, Renan, Perez, Rolando, Phillips, Richard, Pongpattananurak, Nantachai, Sun, I-Fang, Swanson, Mark, Tan, Sylvester, Thomas, Duncan, Thompson, Jill, Uriarte, Maria, Wolf, Amy, Yao, Tze, Zimmerman, Jess, Zuleta, Daniel, Hartig, Florian, Hülsmann, Lisa, Chisholm, Ryan, Comita, Liza, Visser, Marco, de Souza Leite, Melina, Aguilar, Salomon, Anderson-Teixeira, Kristina, Bourg, Norman, Brockelman, Warren, Bunyavejchewin, Sarayudh, Castaño, Nicolas, Chang-Yang, Chia-Hao, Chuyong, George, Clay, Keith, Davies, Stuart, Duque, Alvaro, Ediriweera, Sisira, Ewango, Corneille, and Gilbert, Gregory|Greg

Subjects

Seedlings, Tropical Climate, Forests, Trees, Biodiversity, Ecosystem

Abstract

Numerous studies have shown reduced performance in plants that are surrounded by neighbours of the same species1,2, a phenomenon known as conspecific negative density dependence (CNDD)3. A long-held ecological hypothesis posits that CNDD is more pronounced in tropical than in temperate forests4,5, which increases community stabilization, species coexistence and the diversity of local tree species6,7. Previous analyses supporting such a latitudinal gradient in CNDD8,9 have suffered from methodological limitations related to the use of static data10-12. Here we present a comprehensive assessment of latitudinal CNDD patterns using dynamic mortality data to estimate species-site-specific CNDD across 23 sites. Averaged across species, we found that stabilizing CNDD was present at all except one site, but that average stabilizing CNDD was not stronger toward the tropics. However, in tropical tree communities, rare and intermediate abundant species experienced stronger stabilizing CNDD than did common species. This pattern was absent in temperate forests, which suggests that CNDD influences species abundances more strongly in tropical forests than it does in temperate ones13. We also found that interspecific variation in CNDD, which might attenuate its stabilizing effect on species diversity14,15, was high but not significantly different across latitudes. Although the consequences of these patterns for latitudinal diversity gradients are difficult to evaluate, we speculate that a more effective regulation of population abundances could translate into greater stabilization of tropical tree communities and thus contribute to the high local diversity of tropical forests.

Published

2024

16. Inferring forest fate from demographic data: from vital rates to population dynamic models

Author

Needham, Jessica, Merow, Cory, Chang-Yang, Chia-Hao, Caswell, Hal, and McMahon, Sean M

Subjects

Demography, Forests, Models, Biological, Panama, Population Dynamics, Species Specificity, Trees, Tropical Climate, forest ecology, demography, individual-based models, integral projection models, population projections, life-history strategies, Biological Sciences, Agricultural and Veterinary Sciences, Medical and Health Sciences

Abstract

As population-level patterns of interest in forests emerge from individual vital rates, modelling forest dynamics requires making the link between the scales at which data are collected (individual stems) and the scales at which questions are asked (e.g. populations and communities). Structured population models (e.g. integral projection models (IPMs)) are useful tools for linking vital rates to population dynamics. However, the application of such models to forest trees remains challenging owing to features of tree life cycles, such as slow growth, long lifespan and lack of data on crucial ontogenic stages. We developed a survival model that accounts for size-dependent mortality and a growth model that characterizes individual heterogeneity. We integrated vital rate models into two types of population model; an analytically tractable form of IPM and an individual-based model (IBM) that is applied with stochastic simulations. We calculated longevities, passage times to, and occupancy time in, different life cycle stages, important metrics for understanding how demographic rates translate into patterns of forest turnover and carbon residence times. Here, we illustrate the methods for three tropical forest species with varying life-forms. Population dynamics from IPMs and IBMs matched a 34 year time series of data (albeit a snapshot of the life cycle for canopy trees) and highlight differences in life-history strategies between species. Specifically, the greater variation in growth rates within the two canopy species suggests an ability to respond to available resources, which in turn manifests as faster passage times and greater occupancy times in larger size classes. The framework presented here offers a novel and accessible approach to modelling the population dynamics of forest trees.

Published

2018