Your search keyword '"Lopez-Gonzalez, Gabriela"' showing total 9 results

1. The persistence of carbon in the African forest understory.

Author

Hubau W, De Mil T, Van den Bulcke J, Phillips OL, Angoboy Ilondea B, Van Acker J, Sullivan MJP, Nsenga L, Toirambe B, Couralet C, Banin LF, Begne SK, Baker TR, Bourland N, Chezeaux E, Clark CJ, Collins M, Comiskey JA, Cuni-Sanchez A, Deklerck V, Dierickx S, Doucet JL, Ewango CEN, Feldpausch TR, Gilpin M, Gonmadje C, Hall JS, Harris DJ, Hardy OJ, Kamdem MD, Kasongo Yakusu E, Lopez-Gonzalez G, Makana JR, Malhi Y, Mbayu FM, Moore S, Mukinzi J, Pickavance G, Poulsen JR, Reitsma J, Rousseau M, Sonké B, Sunderland T, Taedoumg H, Talbot J, Tshibamba Mukendi J, Umunay PM, Vleminckx J, White LJT, Zemagho L, Lewis SL, and Beeckman H

Subjects

Carbon Cycle, Democratic Republic of the Congo, Time Factors, Trees growth & development, Tropical Climate, Carbon analysis, Carbon Sequestration, Forests, Trees physiology

Abstract

Quantifying carbon dynamics in forests is critical for understanding their role in long-term climate regulation 1-4 . Yet little is known about tree longevity in tropical forests 3,5-8 , a factor that is vital for estimating carbon persistence 3,4 . Here we calculate mean carbon age (the period that carbon is fixed in trees 7 ) in different strata of African tropical forests using (1) growth-ring records with a unique timestamp accurately demarcating 66 years of growth in one site and (2) measurements of diameter increments from the African Tropical Rainforest Observation Network (23 sites). We find that in spite of their much smaller size, in understory trees mean carbon age (74 years) is greater than in sub-canopy (54 years) and canopy (57 years) trees and similar to carbon age in emergent trees (66 years). The remarkable carbon longevity in the understory results from slow and aperiodic growth as an adaptation to limited resource availability 9-11 . Our analysis also reveals that while the understory represents a small share (11%) of the carbon stock 12,13 , it contributes disproportionally to the forest carbon sink (20%). We conclude that accounting for the diversity of carbon age and carbon sequestration among different forest strata is critical for effective conservation management 14-16 and for accurate modelling of carbon cycling 4 .

Published

2019

2. Diversity and carbon storage across the tropical forest biome.

Author

Sullivan MJ, Talbot J, Lewis SL, Phillips OL, Qie L, Begne SK, Chave J, Cuni-Sanchez A, Hubau W, Lopez-Gonzalez G, Miles L, Monteagudo-Mendoza A, Sonké B, Sunderland T, Ter Steege H, White LJ, Affum-Baffoe K, Aiba SI, de Almeida EC, de Oliveira EA, Alvarez-Loayza P, Dávila EÁ, Andrade A, Aragão LE, Ashton P, Aymard C GA, Baker TR, Balinga M, Banin LF, Baraloto C, Bastin JF, Berry N, Bogaert J, Bonal D, Bongers F, Brienen R, Camargo JL, Cerón C, Moscoso VC, Chezeaux E, Clark CJ, Pacheco ÁC, Comiskey JA, Valverde FC, Coronado EN, Dargie G, Davies SJ, De Canniere C, Djuikouo K MN, Doucet JL, Erwin TL, Espejo JS, Ewango CE, Fauset S, Feldpausch TR, Herrera R, Gilpin M, Gloor E, Hall JS, Harris DJ, Hart TB, Kartawinata K, Kho LK, Kitayama K, Laurance SG, Laurance WF, Leal ME, Lovejoy T, Lovett JC, Lukasu FM, Makana JR, Malhi Y, Maracahipes L, Marimon BS, Junior BH, Marshall AR, Morandi PS, Mukendi JT, Mukinzi J, Nilus R, Vargas PN, Camacho NC, Pardo G, Peña-Claros M, Pétronelli P, Pickavance GC, Poulsen AD, Poulsen JR, Primack RB, Priyadi H, Quesada CA, Reitsma J, Réjou-Méchain M, Restrepo Z, Rutishauser E, Salim KA, Salomão RP, Samsoedin I, Sheil D, Sierra R, Silveira M, Slik JW, Steel L, Taedoumg H, Tan S, Terborgh JW, Thomas SC, Toledo M, Umunay PM, Gamarra LV, Vieira IC, Vos VA, Wang O, Willcock S, and Zemagho L

Subjects

Africa, Americas, Asia, Tropical Climate, Biodiversity, Carbon analysis, Forests, Plants chemistry, Plants classification

Abstract

Tropical forests are global centres of biodiversity and carbon storage. Many tropical countries aspire to protect forest to fulfil biodiversity and climate mitigation policy targets, but the conservation strategies needed to achieve these two functions depend critically on the tropical forest tree diversity-carbon storage relationship. Assessing this relationship is challenging due to the scarcity of inventories where carbon stocks in aboveground biomass and species identifications have been simultaneously and robustly quantified. Here, we compile a unique pan-tropical dataset of 360 plots located in structurally intact old-growth closed-canopy forest, surveyed using standardised methods, allowing a multi-scale evaluation of diversity-carbon relationships in tropical forests. Diversity-carbon relationships among all plots at 1 ha scale across the tropics are absent, and within continents are either weak (Asia) or absent (Amazonia, Africa). A weak positive relationship is detectable within 1 ha plots, indicating that diversity effects in tropical forests may be scale dependent. The absence of clear diversity-carbon relationships at scales relevant to conservation planning means that carbon-centred conservation strategies will inevitably miss many high diversity ecosystems. As tropical forests can have any combination of tree diversity and carbon stocks both require explicit consideration when optimising policies to manage tropical carbon and biodiversity.

Published

2017

3. Increasing carbon storage in intact African tropical forests.

Author

Lewis SL, Lopez-Gonzalez G, Sonké B, Affum-Baffoe K, Baker TR, Ojo LO, Phillips OL, Reitsma JM, White L, Comiskey JA, Djuikouo K MN, Ewango CE, Feldpausch TR, Hamilton AC, Gloor M, Hart T, Hladik A, Lloyd J, Lovett JC, Makana JR, Malhi Y, Mbago FM, Ndangalasi HJ, Peacock J, Peh KS, Sheil D, Sunderland T, Swaine MD, Taplin J, Taylor D, Thomas SC, Votere R, and Wöll H

Subjects

Africa, Atmosphere chemistry, Biomass, Carbon analysis, Carbon Dioxide analysis, Carbon Dioxide metabolism, Models, Biological, Trees anatomy & histology, Trees chemistry, Trees growth & development, Wilderness, Wood analysis, Wood chemistry, Carbon metabolism, Trees metabolism, Tropical Climate

Abstract

The response of terrestrial vegetation to a globally changing environment is central to predictions of future levels of atmospheric carbon dioxide. The role of tropical forests is critical because they are carbon-dense and highly productive. Inventory plots across Amazonia show that old-growth forests have increased in carbon storage over recent decades, but the response of one-third of the world's tropical forests in Africa is largely unknown owing to an absence of spatially extensive observation networks. Here we report data from a ten-country network of long-term monitoring plots in African tropical forests. We find that across 79 plots (163 ha) above-ground carbon storage in live trees increased by 0.63 Mg C ha(-1) yr(-1) between 1968 and 2007 (95% confidence interval (CI), 0.22-0.94; mean interval, 1987-96). Extrapolation to unmeasured forest components (live roots, small trees, necromass) and scaling to the continent implies a total increase in carbon storage in African tropical forest trees of 0.34 Pg C yr(-1) (CI, 0.15-0.43). These reported changes in carbon storage are similar to those reported for Amazonian forests per unit area, providing evidence that increasing carbon storage in old-growth forests is a pan-tropical phenomenon. Indeed, combining all standardized inventory data from this study and from tropical America and Asia together yields a comparable figure of 0.49 Mg C ha(-1) yr(-1) (n = 156; 562 ha; CI, 0.29-0.66; mean interval, 1987-97). This indicates a carbon sink of 1.3 Pg C yr(-1) (CI, 0.8-1.6) across all tropical forests during recent decades. Taxon-specific analyses of African inventory and other data suggest that widespread changes in resource availability, such as increasing atmospheric carbon dioxide concentrations, may be the cause of the increase in carbon stocks, as some theory and models predict.

Published

2009

4. Markedly divergent estimates of Amazon forest carbon density from ground plots and satellites

Author

Mitchard, Edward T. A., Feldpausch, Ted R., Brienen, Roel J. W., Lopez-Gonzalez, Gabriela, Monteagudo, Abel, Baker, Timothy R., Lewis, Simon L., Lloyd, Jon, Quesada, Carlos A., Gloor, Manuel, Steege, Hans ter, Meir, Patrick, Alvarez, Esteban, Araujo-Murakami, Alejandro, Aragão, Luiz E. O. C., Arroyo, Luzmila, Aymard, Gerardo, Banki, Olaf, Bonal, Damien, Brown, Sandra, Brown, Foster I., Cerón, Carlos E., Moscoso, Victor Chama, Chave, Jerome, Comiskey, James A., Cornejo, Fernando, Medina, Massiel Corrales, Da Costa, Lola, Costa, Flavia R. C., Di Fiore, Anthony, Domingues, Tomas F., Erwin, Terry L., Frederickson, Todd, Higuchi, Niro, Coronado, Euridice N. Honorio, Killeen, Tim J., Laurance, William F., Levis, Carolina, Magnusson, William E., Marimon, Beatriz S., Marimon, Ben Hur, Polo, Irina Mendoza, Mishra, Piyush, Nascimento, Marcelo T., Neill, David, Vargas, Mario P. Núñez, Palacios, Walter A., Parada, Alexander, Molina, Guido Pardo, Peña-Claros, Marielos, Pitman, Nigel, Peres, Carlos A., Poorter, Lourens, Prieto, Adriana, Ramirez-Angulo, Hirma, Correa, Zorayda Restrepo, Roopsind, Anand, Roucoux, Katherine H., Rudas, Agustin, Salomão, Rafael P., Schietti, Juliana, Silveira, Marcos, de Souza, Priscila F., Steininger, Marc K., Stropp, Juliana, Terborgh, John, Thomas, Raquel, Toledo, Marisol, Torres-Lezama, Armando, van Andel, Tinde R., van der Heijden, Geertje M. F., Vieira, Ima C. G., Vieira, Simone, Vilanova-Torre, Emilio, Vos, Vincent A., Wang, Ophelia, Zartman, Charles E., Malhi, Yadvinder, and Phillips, Oliver L.

Published

2014

5. Water table depth modulates productivity and biomass across Amazonian forests

Author

Sousa, Thaiane R., Schietti, Juliana, Ribeiro, Igor O., Emílio, Thaise, Fernández, Rafael Herrera, ter Steege, Hans, Castilho, Carolina V., Esquivel-Muelbert, Adriane, Baker, Timothy, Pontes-Lopes, Aline, Silva, Camila V.J., Silveira, Juliana M., Derroire, Géraldine, Castro, Wendeson, Mendoza, Abel Monteagudo, Ruschel, Ademir, Prieto, Adriana, Lima, Adriano José Nogueira, Rudas, Agustín, Araujo-Murakami, Alejandro, Gutierrez, Alexander Parada, Andrade, Ana, Roopsind, Anand, Manzatto, Angelo Gilberto, Di Fiore, Anthony, Torres-Lezama, Armando, Dourdain, Aurélie, Marimon, Beatriz, Marimon, Ben Hur, Burban, Benoit, van Ulft, Bert, Herault, Bruno, Quesada, Carlos, Mendoza, Casimiro, Stahl, Clement, Bonal, Damien, Galbraith, David, Neill, David, de Oliveira, Edmar A., Hase, Eduardo, Jimenez-Rojas, Eliana, Vilanova, Emilio, Arets, Eric, Berenguer, Erika, Alvarez-Davila, Esteban, Honorio Coronado, Eurídice N., Almeida, Everton, Coelho, Fernanda, Valverde, Fernando Cornejo, Elias, Fernando, Brown, Foster, Bongers, Frans, Arevalo, Freddy Ramirez, Lopez-Gonzalez, Gabriela, van der Heijden, Geertje, Aymard C., Gerardo A., Llampazo, Gerardo Flores, Pardo, Guido, Ramírez-Angulo, Hirma, do Amaral, Iêda Leão, Vieira, Ima Célia Guimarães, Huamantupa-Chuquimaco, Isau, Comiskey, James A., Singh, James, Espejo, Javier Silva, del Aguila-Pasquel, Jhon, Zwerts, Joeri Alexander, Talbot, Joey, Terborgh, John, Ferreira, Joice, Barroso, Jorcely G., Barlow, Jos, Camargo, José Luís, Stropp, Juliana, Peacock, Julie, Serrano, Julio, Melgaço, Karina, Ferreira, Leandro V., Blanc, Lilian, Poorter, Lourens, Gamarra, Luis Valenzuela, Aragão, Luiz, Arroyo, Luzmila, Silveira, Marcos, Peñuela-Mora, Maria Cristina, Vargas, Mario Percy Núñez, Toledo, Marisol, Disney, Mat, Réjou-Méchain, Maxime, Baisie, Michel, Kalamandeen, Michelle, Camacho, Nadir Pallqui, Cardozo, Nállarett Dávila, Silva, Natalino, Pitman, Nigel, Higuchi, Niro, Banki, Olaf, Loayza, Patricia Alvarez, Graça, Paulo M.L.A., Morandi, Paulo S., van der Meer, Peter J., van der Hout, Peter, Naisso, Pétrus, Camargo, Plínio Barbosa, Salomão, Rafael, Thomas, Raquel, Boot, Rene, Umetsu, Ricardo Keichi, da Costa Silva, Richarlly, Burnham, Robyn, Zagt, Roderick, Martinez, Rodolfo Vasquez, Brienen, Roel, Ribeiro, Sabina Cerruto, Lewis, Simon L., Vieira, Simone Aparecida, de Almeida Reis, Simone Matias, Fauset, Sophie, Laurance, Susan, Feldpausch, Ted, Erwin, Terry, Killeen, Timothy, Wortel, Verginia, Moscoso, Victor Chama, Vos, Vincent, Huasco, Walter Huaraca, Laurance, William, Malhi, Yadvinder, Magnusson, William E., Phillips, Oliver L., Costa, Flávia R.C., Animal Behaviour and Cognition, Sub Animal Behaviour and Cognition, Sub Ecology and Biodiversity, Ecology and Biodiversity, Animal Behaviour and Cognition, Sub Animal Behaviour and Cognition, Sub Ecology and Biodiversity, Ecology and Biodiversity, and University of St Andrews. School of Geography & Sustainable Development

Subjects

forest dynamics, Evolution, Bos- en Landschapsecologie, tropical ecology, Behavior and Systematics, groundwater, SDG 13 - Climate Action, Forest and Landscape Ecology, Bosecologie en Bosbeheer, Vegetatie, Ecology, Evolution, Behavior and Systematics, above-ground biomass, MCC, Global and Planetary Change, GE, Vegetation, Ecology, seasonality, carbon, DAS, PE&RC, AC, Forest Ecology and Forest Management, Vegetatie, Bos- en Landschapsecologie, Vegetation, Forest and Landscape Ecology, GE Environmental Sciences

Abstract

Funding: This work was part of the PhD thesis of the first author, developed at the Graduate Program in Ecology of the National Institute of Amazonian Research (INPA), with a fellowship funded by Coordenação de Aperfeiçoamento de Pessoal de Nível Superior – Brasil (CAPES), Finance Code 001, (88887.141433/2017-00). The authors are also grateful for the financial and research support of the Conselho Nacional de Desenvolvimento Científico e Tecnológico (CNPq), Amazonas State Research Foundation (FAPEAM), the Newton Fund via the Natural Environment Research Council (NE/M022021/1 to O.L.P. and F.R.C.C.), PPBio Manaus, Centro de Estudos Integrados da Biodiversidade Amazônica and RAINFOR. We also thank Karina Melgaço, Aurora Levesley and Gabriela Lopez-Gonzalez for curating and managing ForestPlots.net. This was ForestPlots.net Project 26 led by Thaiane Sousa. This is publication number 832 of the Technical Series of the Biological Dynamics of Forest Fragments Project (BDFFP, INPA/STRI). Aim : Water availability is the major driver of tropical forest structure and dynamics. Most research has focused on the impacts of climatic water availability, whereas remarkably little is known about the influence of water table depth and excess soil water on forest processes. Nevertheless, given that plants take up water from the soil, the impacts of climatic water supply on plants are likely to be modulated by soil water conditions. Location : Lowland Amazonian forests. Time period : 1971–2019. Methods : We used 344 long-term inventory plots distributed across Amazonia to analyse the effects of long-term climatic and edaphic water supply on forest functioning. We modelled forest structure and dynamics as a function of climatic, soil-water and edaphic properties. Results : Water supplied by both precipitation and groundwater affects forest structure and dynamics, but in different ways. Forests with a shallow water table (depth

Published

2022

6. Drought Sensitivity of the Amazon Rainforest

Author

Phillips, Oliver L., Aragão, Luiz E. O. C., Lewis, Simon L., Fisher, Joshua B., Lloyd, Jon, López-González, Gabriela, Malhi, Yadvinder, Monteagudo, Abel, Peacock, Julie, Quesada, Carlos A., van der Heijden, Geertje, Almeida, Samuel, Amaral, Iêda, Arroyo, Luzmila, Aymard, Gerardo, Baker, Tim R., Bánki, Olaf, Blanc, Lilian, Bonal, Damien, Brando, Paulo, Chave, Jerome, de Oliveira, Átila Cristina Alves, Cardozo, Nallaret Dávila, Czimczik, Claudia I., Feldpausch, Ted R., Freitas, Maria Aparecida, Gloor, Emanuel, Higuchi, Niro, Jiménez, Eliana, Lloyd, Gareth, Meir, Patrick, Mendoza, Casimiro, Morel, Alexandra, Neill, David A., Nepstad, Daniel, Patiño, Sandra, Peñuela, Maria Cristina, Prieto, Adriana, Ramírez, Fredy, Schwarz, Michael, Silva, Javier, Silveira, Marcos, Thomas, Anne Sota, Steege, Hans ter, Stropp, Juliana, Vásquez, Rodolfo, Zelazowski, Przemyslaw, Dávila, Esteban Alvarez, Andelman, Sandy, Andrade, Ana, Chao, Kuo-Jung, Erwin, Terry, Di Fiore, Anthony, C., Eurídice Honorio, Keeling, Helen, Killeen, Tim J., Laurance, William F., Cruz, Antonio Peña, Pitman, Nigel C. A., Vargas, Percy Núñez, Ramírez-Angulo, Hirma, Rudas, Agustín, Salamão, Rafael, Silva, Natalino, Terborgh, John, and Torres-Lezama, Armando

Published

2009

7. Variation in stem mortality rates determines patterns of above-ground biomass in Amazonian forests: implications for dynamic global vegetation models.

Author

Johnson, Michelle O., Galbraith, David, Gloor, Manuel, De Deurwaerder, Hannes, Guimberteau, Matthieu, Rammig, Anja, Thonicke, Kirsten, Verbeeck, Hans, Randow, Celso, Monteagudo, Abel, Phillips, Oliver L., Brienen, Roel J. W., Feldpausch, Ted R., Lopez Gonzalez, Gabriela, Fauset, Sophie, Quesada, Carlos A., Christoffersen, Bradley, Ciais, Philippe, Sampaio, Gilvan, and Kruijt, Bart

Subjects

ALLOMETRY, TREE growth, CARBON sequestration in forests, GROUND vegetation cover, TROPICAL forests

Abstract

Understanding the processes that determine above-ground biomass ( AGB) in Amazonian forests is important for predicting the sensitivity of these ecosystems to environmental change and for designing and evaluating dynamic global vegetation models ( DGVMs). AGB is determined by inputs from woody productivity [woody net primary productivity ( NPP)] and the rate at which carbon is lost through tree mortality. Here, we test whether two direct metrics of tree mortality (the absolute rate of woody biomass loss and the rate of stem mortality) and/or woody NPP, control variation in AGB among 167 plots in intact forest across Amazonia. We then compare these relationships and the observed variation in AGB and woody NPP with the predictions of four DGVMs. The observations show that stem mortality rates, rather than absolute rates of woody biomass loss, are the most important predictor of AGB, which is consistent with the importance of stand size structure for determining spatial variation in AGB. The relationship between stem mortality rates and AGB varies among different regions of Amazonia, indicating that variation in wood density and height/diameter relationships also influences AGB. In contrast to previous findings, we find that woody NPP is not correlated with stem mortality rates and is weakly positively correlated with AGB. Across the four models, basin-wide average AGB is similar to the mean of the observations. However, the models consistently overestimate woody NPP and poorly represent the spatial patterns of both AGB and woody NPP estimated using plot data. In marked contrast to the observations, DGVMs typically show strong positive relationships between woody NPP and AGB. Resolving these differences will require incorporating forest size structure, mechanistic models of stem mortality and variation in functional composition in DGVMs. [ABSTRACT FROM AUTHOR]

Published

2016

8. Tropical forest wood production: a cross-continental comparison.

Author

Banin, Lindsay, Lewis, Simon L., Lopez‐Gonzalez, Gabriela, Baker, Timothy R., Quesada, Carlos A., Chao, Kuo‐Jung, Burslem, David F. R. P., Nilus, Reuben, Abu Salim, Kamariah, Keeling, Helen C., Tan, Sylvester, Davies, Stuart J., Monteagudo Mendoza, Abel, Vásquez, Rodolfo, Lloyd, Jon, Neill, David A., Pitman, Nigel, Phillips, Oliver L., and Wurzburger, Nina

Subjects

TROPICAL forests, WOOD products, EFFECT of environment on plants, CARBON cycle, SOIL fertility, DIPTEROCARPACEAE

Abstract

1. Tropical forest above-ground wood production (AGWP) varies substantially along environmental gradients. Some evidence suggests that AGWP may vary between regions and specifically that Asian forests have particularly high AGWP. However, comparisons across biogeographic regions using standardized methods are lacking, limiting our assessment of pan-tropical variation in AGWP and potential causes. 2. We sampled AGWP in NW Amazon (17 long-term forest plots) and N Borneo (11 plots), both with abundant year-round precipitation. Within each region, forests growing on a broad range of edaphic conditions were sampled using standardized soil and forest measurement techniques. 3. Plot-level AGWP was 49% greater in Borneo than in Amazonia (9.73 ± 0.56 vs. 6.53 ± 0.34 Mg dry mass ha-1 a-1, respectively; regional mean ± 1 SE). AGWP was positively associated with soil fertility (PCA axes, sum of bases and total P). After controlling for the edaphic environment,AGWP remained significantly higher in Bornean plots. Differences in AGWP were largely attributable to differing height-diameter allometry in the two regions and the abundance of large trees in Borneo. This may be explained, in part, by the greater solar radiation in Borneo compared with NWAmazonia. 4. Trees belonging to the dominant SE Asian family, Dipterocarpaceae, gained woody biomass faster than otherwise equivalent, neighbouring non-dipterocarps, implying that the exceptional production of Bornean forests may be driven by floristic elements. This dominant SE Asian family may partition biomass differently or be more efficient at harvesting resources and in converting themto woody biomass. 5. Synthesis. N Bornean forests have much greater AGWP rates than those in NW Amazon when soil conditions and rainfall are controlled for. Greater resource availability and the highly productive dipterocarps may, in combination, explain why Asian forests produce wood half as fast again as comparable forests in the Amazon. Our results also suggest that taxonomic groups differ in their fundamental ability to capture carbon and that different tropical regions may therefore have different carbon uptake capacities due to biogeographic history. [ABSTRACT FROM AUTHOR]

Published

2014

9. Methods to estimate aboveground wood productivity from long-term forest inventory plots.

Author

Talbot, Joey, Lewis, Simon L., Lopez-Gonzalez, Gabriela, Brienen, Roel J.W., Monteagudo, Abel, Baker, Timothy R., Feldpausch, Ted R., Malhi, Yadvinder, Vanderwel, Mark, Araujo Murakami, Alejandro, Arroyo, Luzmila P., Chao, Kuo-Jung, Erwin, Terry, van der Heijden, Geertje, Keeling, Helen, Killeen, Tim, Neill, David, Núñez Vargas, Percy, Parada Gutierrez, Germaine Alexander, and Pitman, Nigel

Subjects

SUSTAINABLE forestry, WOOD products, FOREST surveys, FORESTS & forestry

Abstract

Highlights: [•] We develop analytical methods for estimating wood production in forest plots. [•] Our corrections provide suggested methods to minimise three time-sensitive biases. [•] In Amazonia, uncorrected estimates of wood production are underestimated by 13%. [ABSTRACT FROM AUTHOR]

Published

2014