Your search keyword '"Schnitzer, Stefan A."' showing total 7 results

1. Liana optical traits increase tropical forest albedo and reduce ecosystem productivity

Author

Meunier, Félicien, Visser, Marco D, Shiklomanov, Alexey, Dietze, Michael C, Q., J Antonio Guzmán, Sanchez‐Azofeifa, G Arturo, De Deurwaerder, Hannes PT, Moorthy, Sruthi M Krishna, Schnitzer, Stefan A, Marvin, David C, Longo, Marcos, Liu, Chang, Broadbent, Eben N, Zambrano, Angelica M Almeyda, Muller‐Landau, Helene C, Detto, Matteo, and Verbeeck, Hans

Subjects

Biological Sciences, Ecology, Bayes Theorem, Carbon Cycle, Ecosystem, Forests, Tropical Climate, ecosystem demography model, forest albedo, forest energy balance, PROSPECT-5, radiative transfer models, structural parasitism, tropical lianas, Environmental Sciences, Biological sciences, Earth sciences, Environmental sciences

Abstract

Lianas are a key growth form in tropical forests. Their lack of self-supporting tissues and their vertical position on top of the canopy make them strong competitors of resources. A few pioneer studies have shown that liana optical traits differ on average from those of colocated trees. Those trait discrepancies were hypothesized to be responsible for the competitive advantage of lianas over trees. Yet, in the absence of reliable modelling tools, it is impossible to unravel their impact on the forest energy balance, light competition, and on the liana success in Neotropical forests. To bridge this gap, we performed a meta-analysis of the literature to gather all published liana leaf optical spectra, as well as all canopy spectra measured over different levels of liana infestation. We then used a Bayesian data assimilation framework applied to two radiative transfer models (RTMs) covering the leaf and canopy scales to derive tropical tree and liana trait distributions, which finally informed a full dynamic vegetation model. According to the RTMs inversion, lianas grew thinner, more horizontal leaves with lower pigment concentrations. Those traits made the lianas very efficient at light interception and significantly modified the forest energy balance and its carbon cycle. While forest albedo increased by 14% in the shortwave, light availability was reduced in the understorey (-30% of the PAR radiation) and soil temperature decreased by 0.5°C. Those liana-specific traits were also responsible for a significant reduction of tree (-19%) and ecosystem (-7%) gross primary productivity (GPP) while lianas benefited from them (their GPP increased by +27%). This study provides a novel mechanistic explanation to the increase in liana abundance, new evidence of the impact of lianas on forest functioning, and paves the way for the evaluation of the large-scale impacts of lianas on forest biogeochemical cycles.

Published

2022

2. Modeling the impact of liana infestation on the demography and carbon cycle of tropical forests.

Author

di Porcia E Brugnera, Manfredo, Meunier, Félicien, Longo, Marcos, Krishna Moorthy, Sruthi M, De Deurwaerder, Hannes, Schnitzer, Stefan A, Bonal, Damien, Faybishenko, Boris, and Verbeeck, Hans

Subjects

Trees, Ecosystem, Tropical Climate, Demography, Panama, Carbon Cycle, Forests, carbon dynamics, dynamic global vegetation model, ecology, lianas, plant functional type, tropical forest, Ecology, Biological Sciences, Environmental Sciences

Abstract

There is mounting empirical evidence that lianas affect the carbon cycle of tropical forests. However, no single vegetation model takes into account this growth form, although such efforts could greatly improve the predictions of carbon dynamics in tropical forests. In this study, we incorporated a novel mechanistic representation of lianas in a dynamic global vegetation model (the Ecosystem Demography Model). We developed a liana-specific plant functional type and mechanisms representing liana-tree interactions (such as light competition, liana-specific allometries, and attachment to host trees) and parameterized them according to a comprehensive literature meta-analysis. We tested the model for an old-growth forest (Paracou, French Guiana) and a secondary forest (Gigante Peninsula, Panama). The resulting model simulations captured many features of the two forests characterized by different levels of liana infestation as revealed by a systematic comparison of the model outputs with empirical data, including local census data from forest inventories, eddy flux tower data, and terrestrial laser scanner-derived forest vertical structure. The inclusion of lianas in the simulations reduced the secondary forest net productivity by up to 0.46 tC  ha-1  year-1 , which corresponds to a limited relative reduction of 2.6% in comparison with a reference simulation without lianas. However, this resulted in significantly reduced accumulated above-ground biomass after 70 years of regrowth by up to 20 tC /ha (19% of the reference simulation). Ultimately, the simulated negative impact of lianas on the total biomass was almost completely cancelled out when the forest reached an old-growth successional stage. Our findings suggest that lianas negatively influence the forest potential carbon sink strength, especially for young, disturbed, liana-rich sites. In light of the critical role that lianas play in the profound changes currently experienced by tropical forests, this new model provides a robust numerical tool to forecast the impact of lianas on tropical forest carbon sinks.

Published

2019

3. Effects of lianas on forest biogeochemistry during their lives and afterlives

Author

Dossa, Gbadamassi G. O., primary, Li, Hong‐Lin, additional, Pan, Bo, additional, Ling, Tial C., additional, Schaefer, Douglas A., additional, Roeder, Mareike, additional, Njoroge, Denis M., additional, Zuo, Juan, additional, Song, Liang, additional, Ofosu‐Bamfo, Bismark, additional, Schnitzer, Stefan A., additional, Harrison, Rhett D., additional, Bongers, Frans, additional, Zhang, Jiao‐Lin, additional, Cao, Kun‐Fang, additional, Powers, Jennifer S., additional, Fan, Ze‐Xin, additional, Chen, Ya‐Jun, additional, Corlett, Richard T., additional, Zotz, Gerhard, additional, Oleksyn, Jacek, additional, Wyka, Tomasz P., additional, Codjia, Jean Evans Israel, additional, and Cornelissen, Johannes H. C., additional

Published

2024

4. Liana optical traits increase tropical forest albedo and reduce ecosystem productivity

Author

Meunier, Félicien, primary, Visser, Marco D., additional, Shiklomanov, Alexey, additional, Dietze, Michael C., additional, Guzmán Q., J. Antonio, additional, Sanchez‐Azofeifa, G. Arturo, additional, De Deurwaerder, Hannes P. T., additional, Krishna Moorthy, Sruthi M., additional, Schnitzer, Stefan A., additional, Marvin, David C., additional, Longo, Marcos, additional, Liu, Chang, additional, Broadbent, Eben N., additional, Almeyda Zambrano, Angelica M., additional, Muller‐Landau, Helene C., additional, Detto, Matteo, additional, and Verbeeck, Hans, additional

Published

2021

5. Modeling the impact of liana infestation on the demography and carbon cycle of tropical forests.

Author

Porcia e Brugnera, Manfredo, Meunier, Félicien, Longo, Marcos, Krishna Moorthy, Sruthi M., De Deurwaerder, Hannes, Schnitzer, Stefan A., Bonal, Damien, Faybishenko, Boris, and Verbeeck, Hans

Subjects

TROPICAL forests, OPTICAL scanners, CARBON cycle, LIANAS, SECONDARY forests, FOREST surveys

Abstract

There is mounting empirical evidence that lianas affect the carbon cycle of tropical forests. However, no single vegetation model takes into account this growth form, although such efforts could greatly improve the predictions of carbon dynamics in tropical forests. In this study, we incorporated a novel mechanistic representation of lianas in a dynamic global vegetation model (the Ecosystem Demography Model). We developed a liana‐specific plant functional type and mechanisms representing liana–tree interactions (such as light competition, liana‐specific allometries, and attachment to host trees) and parameterized them according to a comprehensive literature meta‐analysis. We tested the model for an old‐growth forest (Paracou, French Guiana) and a secondary forest (Gigante Peninsula, Panama). The resulting model simulations captured many features of the two forests characterized by different levels of liana infestation as revealed by a systematic comparison of the model outputs with empirical data, including local census data from forest inventories, eddy flux tower data, and terrestrial laser scanner‐derived forest vertical structure. The inclusion of lianas in the simulations reduced the secondary forest net productivity by up to 0.46 tC ha−1 year−1, which corresponds to a limited relative reduction of 2.6% in comparison with a reference simulation without lianas. However, this resulted in significantly reduced accumulated above‐ground biomass after 70 years of regrowth by up to 20 tC/ha (19% of the reference simulation). Ultimately, the simulated negative impact of lianas on the total biomass was almost completely cancelled out when the forest reached an old‐growth successional stage. Our findings suggest that lianas negatively influence the forest potential carbon sink strength, especially for young, disturbed, liana‐rich sites. In light of the critical role that lianas play in the profound changes currently experienced by tropical forests, this new model provides a robust numerical tool to forecast the impact of lianas on tropical forest carbon sinks. [ABSTRACT FROM AUTHOR]

Published

2019

6. No evidence that elevated CO2 gives tropical lianas an advantage over tropical trees

Author

Marvin, David C., primary, Winter, Klaus, additional, Burnham, Robyn J., additional, and Schnitzer, Stefan A., additional

Published

2015

7. No evidence that elevated CO2 gives tropical lianas an advantage over tropical trees.

Author

Marvin, David C., Winter, Klaus, Burnham, Robyn J., and Schnitzer, Stefan A.

Subjects

LIANAS, TROPICAL forests, ATMOSPHERIC carbon dioxide, PLANT growth, PLANT mortality

Abstract

Recent studies indicate that lianas are increasing in size and abundance relative to trees in neotropical forests. As a result, forest dynamics and carbon balance may be altered through liana-induced suppression of tree growth and increases in tree mortality. Increasing atmospheric CO2 is hypothesized to be responsible for the increase in neotropical lianas, yet no study has directly compared the relative response of tropical lianas and trees to elevated CO2. We explicitly tested whether tropical lianas had a larger response to elevated CO2 than co-occurring tropical trees and whether seasonal drought alters the response of either growth form. In two experiments conducted in central Panama, one spanning both wet and dry seasons and one restricted to the dry season, we grew liana ( n = 12) and tree ( n = 10) species in open-top growth chambers maintained at ambient or twice-ambient CO2 levels. Seedlings of eight individuals (four lianas, four trees) were grown in the ground in each chamber for at least 3 months during each season. We found that both liana and tree seedlings had a significant and positive response to elevated CO2 (in biomass, leaf area, leaf mass per area, and photosynthesis), but that the relative response to elevated CO2 for all variables was not significantly greater for lianas than trees regardless of the season. The lack of differences in the relative response between growth forms does not support the hypothesis that elevated CO2 is responsible for increasing liana size and abundance across the neotropics. [ABSTRACT FROM AUTHOR]

Published

2015