IMPACTS OF CLIMATE CHANGE ON THE NATURAL DISTRIBUTION OF SPECIES OF LOWLAND HIGH AND LOW IN THE AMAZON

Souza, Diulio Andrew Torres de; Lima, Alexandra Amaro de; Wrege, Marcos Silveira; Aguiar, Ananda Virginia de; Bezerra, Caroline de Souza; Meneses, Carlos Henrique Salvino Gadêlha; Lopes, Ricardo; Ramos, Santiago Linorio Ferreyra; Paranatinga, Iasmin Laís Damasceno; Lopes, Maria Teresa Gomes

doi:10.53661/1806-9088202448263751

ABSTRACT

The areas of Amazonian floodplains have added ecological value to their multiple ecosystem services, including water supply, local climate regulation, biodiversity with a marked number of endemic species, and diversity of micro-habitat. Considering the importance of conserving these environments, this study aimed to analyze the behavior and delimit the areas of the natural distribution of forest species Alchornea castaneifolia (Willd.) A. Juss and Laetia corymbulosa (lowland low), Maquira coriacea (H.Karst.) C.C. Berg (Moraceae), and Ocotea cymbarum Kunth (high floodplain), besides evaluating the potential impacts of climate change on the future distribution inferring on its conservation. The potential species distribution was modeled using Environmental Modelling & Software, by employing algorithms such as Bioclim, Domain, Maximum Entropy, Random Forests, and Support Vector Machine (SVM). The projections indicate that climate change threatens the occurrence of floodplain species. Under the SSP 585 scenario for both periods, the four species studied will lose areas of climatic adequacy until the end of the 21st century, especially in the Brazilian Amazon. The study shows the need to increase socio-environmental responsibility through conserving current protected areas in freshwater ecosystems and implementing new priority areas for conserving wetlands (Ramsar Sites) in the Amazon. Such measures are essential to ensure in situ conservation and protect them from habitat loss.

Keywords:
Forest conservation; Wetlands; Protected areas

RESUMO

As áreas de várzeas amazônicas possuem valor ecológico agregado aos seus múltiplos serviços ecossistêmicos, incluindo o abastecimento de água, regulagem do clima local, biodiversidade com um número acentuado de espécies endêmicas e com diversidade de micro-habitat. Considerando a importância da conservação desses ambientes, este estudo objetivou analisar o comportamento e delimitar as áreas de distribuição natural das espécies florestais Alchornea castaneifolia (Willd.) A. Juss e Laetia corymbulosa (várzea baixa) e Maquira coriacea (H. Karst.) C.C. Berg (Moraceae) e Ocotea cymbarum Kunth (várzea alta), além de avaliar os impactos potenciais das mudanças climáticas sobre a distribuição futura, inferindo sobre a sua conservação. A modelagem de distribuição potencial das espécies foi feita com o uso do Environmental Modelling & Software, a partir dos algoritmos como: Bioclim, Domain, Maximum Entropy, Random Forests e Support Vector Machine (SVM). As projeções indicam que as mudanças climáticas representam ameaça à ocorrência das espécies de várzea. Sob o cenário SSP 585 para ambos os períodos, as quatro espécies estudadas perderão áreas de adequação climática até o final do século XXI, principalmente, na Amazônia brasileira. O estudo mostra a necessidade de aumentar a responsabilidade socioambiental para conservação das áreas protegidas atuais em ecossistemas de água doce e, implementar novas áreas prioritárias para a conservação de zonas úmidas (Sítios Ramsar) na Amazônia. Tais medidas são fundamentais para garantir a conservação in situ e protegê-las de uma perda de habitat.

Palavras-Chave:
Conservação florestal; Áreas úmidas; Áreas protegidas

1. INTRODUCTION

The report of the Intergovernmental Panel on Climate Change (IPCC, 2021Intergovernmental Panel on Climate change - IPCC. Climate change 2021: the physical science basis. summary for policy makers. 2021. [citado 15 jun. 2021]. Disponível em: https://www.ipcc.ch/report/ar6/wg1/downloads/report/IPCCAR6WGIFullReport. pdf.Acesso
https://www.ipcc.ch/report/ar6/wg1/downl... ) shows that the global average temperature projections for the year 2030 may exceed 1.5º C, while Brazil points to an increase of 7.5º C. These global climate changes threaten biodiversity, urban and natural ecosystems (De Faria et al., 2021De Faria BL, Staal A, Silva CA, Martin PA, Panday PK, Dantas VL. Climate change and deforestation increase the vulnerability of Amazonian forests to post-fire grass invasion. Global Ecology and Biogeography. 2021;30(12):2368-2381. doi: https://doi.org/10.1111/geb.13388
https://doi.org/10.1111/geb.13388... ), the hydrological cycle, and the maintenance of life on the planet (Huang et al., 2021Huang M, Ding L, Wang J, Ding C, Tao J. The impacts of climate change on fish growth: A summary of conducted studies and current knowledge. Ecological Indicators. 2021;121:106976. doi: https://doi.org/10.1016/j.ecolind.2020.106976
https://doi.org/10.1016/j.ecolind.2020.1... ).

Influenced by hydrographic, climatic, edaphic, and floristic factors, wetland species have an important role in the Amazon region, especially for the balance of the ecosystem, for the maintenance of riparian forests, as a food source for fish and animals, and others (Wittmann et al., 2022Wittmann F, Householder JE, Piedade MT, Schöngart J, Demarchi LO, Quaresma AC, Junk WJ. A Review of the Ecological and Biogeographic Differences of Amazonian Floodplain Forests. Water. 2022;14(21):3360. doi:https://doi.org/10.3390/w14213360
https://doi.org/10.3390/w14213360... ). Approximately 70% of the floodplain areas of the Amazon are covered by forests (Wittmann et al., 2006Wittmann F, Schöngart J, Montero JC, Motzer T, Junk WJF, Piedade MT, Queiroz HL, Worbes M. Tree species composition and diversity gradients in white-water forests across the Amazon Basin. Journal of Biogeography. 2006;33(8):1334-1347. doi: https://doi.org/10.1111/j.1365-2699.2006.01495.x
https://doi.org/10.1111/j.1365-2699.2006... ). It is one of the ecosystems impacted by man, mainly due to access facilitated by water transport and the use of floodplains for agriculture (Renó; Novo, 2019Renó V, Novo E. Forest depletion gradient along the Amazon floodplain. Ecological Indicators. 2019;98:409-419. doi:https://doi.org/10.1016/j.ecolind.2018.11.019
https://doi.org/10.1016/j.ecolind.2018.1... ).

The remaining floodplain forests are subjected to constant selective cuts to supply local, national, and even international timber markets (Wittmann et al., 2022Wittmann F, Householder JE, Piedade MT, Schöngart J, Demarchi LO, Quaresma AC, Junk WJ. A Review of the Ecological and Biogeographic Differences of Amazonian Floodplain Forests. Water. 2022;14(21):3360. doi:https://doi.org/10.3390/w14213360
https://doi.org/10.3390/w14213360... ). In evaluating the east-west gradient of floodplain forest depletion along the Solimões and Amazonas Rivers, it was found that in the eastern region of the basin, there were more degraded landscapes, showing a reduction in biodiversity (Renó; Novo, 2019Renó V, Novo E. Forest depletion gradient along the Amazon floodplain. Ecological Indicators. 2019;98:409-419. doi:https://doi.org/10.1016/j.ecolind.2018.11.019
https://doi.org/10.1016/j.ecolind.2018.1... ).

The Amazon is the Brazilian biome with the largest number of protected areas in the country, with more than 50% of its area covered by some category of protection (MMA, 2022Ministério do Meio Ambiente - MMA. Cadastro Nacional de Unidades de Conservação. 2022. [citado 05 jan. 2022]. Disponível em: https://app.powerbi.com
https://app.powerbi.com... ). However, the selection of priority areas for conservation is established, mainly, based on data on terrestrial organisms and ecosystems (Frederico et al., 2018Frederico RG, Zuanon J, De Marco Junior P. Amazon protected areas and its ability to protect stream-dwelling fish fauna. Biological Conservation. 2018;219:12-19. doi: https://doi.org/10.1016/j.biocon.2017.12.032
https://doi.org/10.1016/j.biocon.2017.12... ), while the conservation of freshwater ecosystems has been in the background.

To promote the conservation and encourage the sustainable use of wetland environments, Brazil, since 1993, has been a signatory to the Ramsar Convention on Wetlands, a treaty that includes actions for the conservation of wetlands, such as the introduction of Ramsar Sites (RS). However, there are currently only nine Ramsar sites in the Brazilian Amazon, and they are estimated to cover less than a fifth of the region’s wetlands (Anderson et al., 2019Anderson EP, Osborne T, MaldonadoOcampo JA, Mills-Novoa M, Castello L, Montoya M, Encalada AC, Jenkins CN. Energy development reveals blind spots for ecosystem conservation in the Amazon Basin. Frontiers in Ecology and the Environment. 2019;17(9):521-529. doi:https://doi.org/10.1002/fee.2114
https://doi.org/10.1002/fee.2114... ; Hess et al., 2015Hess LL, Melack JM, Affonso AG, Barbosa C, Gastil-Buhl M, Novo EM. Wetlands of the lowland Amazon basin: Extent, vegetative cover, and dual-season inundated area as mapped with JERS-1 synthetic aperture radar. Wetlands. 2015;35(4):745-756. doi: https://doi.org/10.1007/s13157-015-0666-y
https://doi.org/10.1007/s13157-015-0666-... ).

Studies of the potential distribution of forest species through ecological modeling have been carried out to verify their vulnerability to climate change and are essential to inferring the conservation strategies of species. In the methodological approach, it is necessary to use climatic variables and geographic coordinates of the species that can be found in databases, expeditions of research groups, and information recorded in the literature (Cordeiro et al., 2023Cordeiro AL, Tomaz JS, Bezerra CS, Meneses CHSG, Aguiar AV, Wrege MS, Ramos SLF, Fraxe TJP, Lopes MTG. Prediction of the geographic distribution and conservation of Amazonian Palm trees Astrocaryum acaule MART. and Astrocaryum aculeatum MART. Revista Árvore. 2023;47:e4719. doi: https://doi.org/10.1590/1806-908820230000019
https://doi.org/10.1590/1806-90882023000... ).

Climate change causes a reduction in the area suitable for the occurrence of several species of biodiversity (Huang et al., 2021Huang M, Ding L, Wang J, Ding C, Tao J. The impacts of climate change on fish growth: A summary of conducted studies and current knowledge. Ecological Indicators. 2021;121:106976. doi: https://doi.org/10.1016/j.ecolind.2020.106976
https://doi.org/10.1016/j.ecolind.2020.1... ). Based on the results of ecological modeling of the current and future potential distribution of species, it is possible to identify the zones of occurrence in different scenarios to understand habitat preferences and apply conservation measures, avoiding a reduction in biodiversity (Cordeiro et al., 2023Cordeiro AL, Tomaz JS, Bezerra CS, Meneses CHSG, Aguiar AV, Wrege MS, Ramos SLF, Fraxe TJP, Lopes MTG. Prediction of the geographic distribution and conservation of Amazonian Palm trees Astrocaryum acaule MART. and Astrocaryum aculeatum MART. Revista Árvore. 2023;47:e4719. doi: https://doi.org/10.1590/1806-908820230000019
https://doi.org/10.1590/1806-90882023000... ).

The objective of this study was to analyze the behavior and delimit areas of natural distribution of floodplain forest species in the Amazon, in climate change scenarios to verify the current and future distribution of tree species inferring on the conservation of species. In regions of low floodplain were analyzed Alchornea castaneifolia (Willd.) A. Juss (Euphorbiaceae) and Laetia corymbulosa Spruce ex Benth. (Salicaceae) and in areas of high floodplain, Maquira coriacea (H.Karst.) C.C. Berg (Moraceae) and Ocotea cymbarum Kunth (Lauraceae).

2. MATERIAL AND METHODS

The choice of species was based on the classification in high floodplain (HF) and low floodplain (LF) for the representativeness in the distribution of species in the study area.

Wittmann et al. (2006)Wittmann F, Schöngart J, Montero JC, Motzer T, Junk WJF, Piedade MT, Queiroz HL, Worbes M. Tree species composition and diversity gradients in white-water forests across the Amazon Basin. Journal of Biogeography. 2006;33(8):1334-1347. doi: https://doi.org/10.1111/j.1365-2699.2006.01495.x
https://doi.org/10.1111/j.1365-2699.2006... classified species as HF when they establish themselves below 3 meter above the water level, and when they survive flood levels equal to or greater than 3m, they are classified as LF. From this classification, two species of LF were selected for ecological modeling: Alchornea castaneifolia (A. castaneifolia) and Laetia corymbulosa (L. corymbulosa), and two of HF: Maquira coriacea (M. coriacea) and Ocotea cymbarum (O. cymbarum).

Species occurrence points were obtained from the database of the Reference Center for Environmental Information (CRIA, 2021Centro de Referência em Informação Ambiental - CRIA. Projeto speciesLink network. 2021. [citado 22 Jun. 2021]. Disponível em: http://splink.cria.org.br
http://splink.cria.org.br... ), the SpeciesLink platform (CRIA, 2021Centro de Referência em Informação Ambiental - CRIA. Projeto speciesLink network. 2021. [citado 22 Jun. 2021]. Disponível em: http://splink.cria.org.br
http://splink.cria.org.br... ), and the Global Biodiversity Information Facility (GBIF, 2021Global biodiversity information facility - GBIF. 2021. [citado 8 Jul. 2021]. Disponível em: https://www.gbif.org
https://www.gbif.org... ). Initially, 332 points were obtained for A. castaneifolia, 276 for L. corymbulosa, 494 for M. coriacea, and 238 for O. cymbarum. These were submitted for verification of possible errors and inconsistencies regarding the natural distribution area. To reduce the autocorrelation of occurrence data and a possible sampling bias, very close occurrences located within a radius of less than 5 km were eliminated (Aiello-Lammens et al., 2015Aiello-Lammens ME, Boria RA, Radosavljevic A, Vilela B, Anderson RP. SpThin: An R package for spatial thinning of species occurrence records for use in ecological niche models. Ecography. 2015;38(5):541-545. doi: https://doi.org/10.1111/ecog.01132
https://doi.org/10.1111/ecog.01132... ). For this, the Microsoft Excel spreadsheet editor and the Geographic Information System (GIS) software QGIS, version 3.16.13, were used. (QGIS Development Team, 2023).

After quality control of the species’ points of occurrence, there was a reduction in information to 201 (47.74%) for LF species (107 for A. castaneifolia and 94 for L. corymbulosa) and 220 (52.26%) for those from HF (137 for M. coriacea and 83 for O. cymbarum). Figure 1 shows the distribution of species with their respective consistent location points until 2021.

Figure 1
Areas of occurrence. A) Alchornea castaneifolia (LF); B) Laetia corymbulosa (LF); C) Maquira coriacea (HF); D) Ocotea cymbarum (HF).
Figura 1
Áreas de ocorrência: A) Alchornea castaneifolia (LF); B) Laetia corymbulosa (LF); C) Maquira coriacea (HF); D) Ocotea cymbarum (HF).

For modeling the species, 19 bioclimatic variables were considered, including minimum and maximum temperatures and rainfall, originating from the WorldClim database version 2.1., whose layers generated in SIG, containing the variables, had a spatial resolution of 2.5 minutes (4 km²).

To control collinearity between bioclimatic variables, a Principal Component Analysis (PCA) was performed. The Main Components (PCs) with the highest contribution in the analysis were selected, responsible for at least 95% of the total variability of the data (Evangelista-Vale et al., 2021Evangelista-Vale JC, Weihs M, JoséSilva L, Arruda R, Sander NL, Gomides SC, Machado TM, Pires-Oliveira JC, Barros-Rosa L, Castuera-Oliveira L, Matias RAM, Martins-Oliveira AT, Bernardo CSS, Silva-Pereira I, Carnicer C, Carpanedo RS, Eisenlohr PV. Climate change may affect the future of extractivism in the Brazilian Amazon. Biological Conservation. 2021;257:109093. doi: https://doi.org/10.1016/j.biocon.2021.109093
https://doi.org/10.1016/j.biocon.2021.10... ) from the R Environment (R Development Core Team, 2021R Core Team. R: A language and environment for statistical computing. R Foundation for Statistical Computing, Vienna, Austria; 2021. [Acesso em: 06 Jun 2022]. Disponível em: https://www.R-project.org/.
https://www.R-project.org/... ) and its complement RStudio (R Studio Team, 2019RSTUDIO. Undelete and data recovery software. Software livre de ambiente de desenvolvimento integrado para R para análises estatísticas. R version 3.4.1, versão obtida em 9 fev. 2019. Boston, 2019. [acesso em 06 Jun. 2022]. Disponível em: https://www.rstudio.com/
https://www.rstudio.com/... ).

For the species modeling process, the ENMTML package (Andrade et al., 2020Andrade AFAD, Velazco SJE, De Marco Júnior P. ENMTML: An R package for a straightforward construction of complex ecological niche models. Environmental Modelling & Software. 2020;125:104615. doi: https://doi.org/10.1016/j.envsoft.2019.104615
https://doi.org/10.1016/j.envsoft.2019.1... ) of the R environment version 4.1.2 was used. The model was adjusted to generate layers containing the distribution of species throughout South America, using for this purpose a vector layer of the region obtained on the TerraBrasilis platform of the National Institute of Space Research, and public access data.

For the selection of the algorithms with the highest predictive quality for the species modeling process, five models were tested: Bioclim - BIO (Nix, 1986Nix HA. A biogeographic analysis of Australian elapid snakes. Atlas of Elapid Snakes of Australia. Australian Go Government Publishing Service, Canberra, ACT: ed R. Longmore; 1986. pp. 4-15.), Domain - DOM (Carpenter et al., 1993Carpenter G, Gillison AN, Winter J. DOMAIN: a flexible modelling procedure for mapping potential distributions of plants and animals. Biodiversity & Conservation. 1993;2:667-680. doi: https://doi.org/10.1007/BF00051966
https://doi.org/10.1007/BF00051966... ), Maximum Entropy - MXS (Anderson and Gonzalez, 2011Anderson RP, Gonzalez Júnior I. Species-specific tuning increases robustness to sampling bias in models of species distributions: an implementation with Maxent. Ecological Modelling. 2011;222(15):27962811. doi: https://doi.org/10.1016/j.ecolmodel.2011.04.011
https://doi.org/10.1016/j.ecolmodel.2011... ), Random Forests - RDF (Prasad et al., 2006Prasad AM, Iverson LR, Liaw A. Newer classification and regression tree techniques: bagging and random forests for ecological prediction. Ecosystems. 2006;9(2):181-199. doi: https://doi.org/10.1007/s10021-0050054-1
https://doi.org/10.1007/s10021-0050054-1... ), and Support Vector Machine - SVM (Guo et al., 2005Guo Q, Kelly M, Graham CH. Support vector machines for predicting distribution of Sudden Oak Death in California. Ecological modelling. 2005;182(1):75-90. doi: https://doi.org/10.1016/j.ecolmodel.2004.07.012
https://doi.org/10.1016/j.ecolmodel.2004... ). The models were evaluated based on four different metrics: Area under the curve - AUC (Fielding and Bell, 1997Fielding AH, Bell J. A review of methods for the assessment of prediction errors in conservation presence/absence models. Environmental Conservation. Cambridge University Press. 1997;24(1):38-49. doi: https://doi.org/10.1017/S0376892997000088
https://doi.org/10.1017/S037689299700008... ), True Skill Statistic - TSS (Allouche et al., 2006Allouche O, Tsoar A, Kadmon R. Assessing the accuracy of species distribution models: Prevalence, kappa and the true skill statistic (TSS). Journal of Applied Ecology. 2006;43(6):1223-1232. https://doi.org/10.1111/j.1365-2664.2006.01214.x
https://doi.org/10.1111/j.1365-2664.2006... ), Jaccard (Leroy et al., 2018Leroy B, Delsol R, Hugueny B, Meynard CN, Barhoumi C, Barbet-Massin M, Bellard C. Without quality presence-absence data, discrimination metrics such as TSS can be misleading measures of model performance. Journal of Biogeography. 2018;45(9): 1994-2002. doi: https://doi.org/10.1111/jbi.13402
https://doi.org/10.1111/jbi.13402... ), and Sorensen (Leroy et al., 2018Leroy B, Delsol R, Hugueny B, Meynard CN, Barhoumi C, Barbet-Massin M, Bellard C. Without quality presence-absence data, discrimination metrics such as TSS can be misleading measures of model performance. Journal of Biogeography. 2018;45(9): 1994-2002. doi: https://doi.org/10.1111/jbi.13402
https://doi.org/10.1111/jbi.13402... ). Those with values greater than 0.7 in all metrics were considered good models (Fielding and Bell, 1997Fielding AH, Bell J. A review of methods for the assessment of prediction errors in conservation presence/absence models. Environmental Conservation. Cambridge University Press. 1997;24(1):38-49. doi: https://doi.org/10.1017/S0376892997000088
https://doi.org/10.1017/S037689299700008... ; Leroy et al., 2018Leroy B, Delsol R, Hugueny B, Meynard CN, Barhoumi C, Barbet-Massin M, Bellard C. Without quality presence-absence data, discrimination metrics such as TSS can be misleading measures of model performance. Journal of Biogeography. 2018;45(9): 1994-2002. doi: https://doi.org/10.1111/jbi.13402
https://doi.org/10.1111/jbi.13402... ; Allouche et al., 2006Allouche O, Tsoar A, Kadmon R. Assessing the accuracy of species distribution models: Prevalence, kappa and the true skill statistic (TSS). Journal of Applied Ecology. 2006;43(6):1223-1232. https://doi.org/10.1111/j.1365-2664.2006.01214.x
https://doi.org/10.1111/j.1365-2664.2006... ).

From the best metrics tested, a consensus model was built, where the pixel has values 0 and 1, such that 0 corresponds to the locations blue (Figure 2). While the value 1 statistically that are statistically not characterized as represents the regions with suitable climatic climatically suitable for the chosen species conditions for the species, represented by the (Andrade et al., 2020Andrade AFAD, Velazco SJE, De Marco Júnior P. ENMTML: An R package for a straightforward construction of complex ecological niche models. Environmental Modelling & Software. 2020;125:104615. doi: https://doi.org/10.1016/j.envsoft.2019.104615
https://doi.org/10.1016/j.envsoft.2019.1... ), as shown in the map in color red.

Figure 2
Consensus maps of the climatic adaptation areas for Amazonian floodplain species: A) Alchornea castaneifolia (LF); B) Laetia corymbulosa (LF); C) Maquira coriacea (HF); D) Ocotea cymbarum (HF).
Figura 2
Mapas de consensos das áreas de adequação climática para espécies da várzea amazônica: A) Alchornea castaneifolia (LF); B) Laetia corymbulosa (LF); C) Maquira coriacea (HF); D) Ocotea cymbarum (HF).

For future projections, the atmospheric circulation model CNRM-CM6-1 of CNRM-CERFACS (National Center for Meteorological Research and European Center for Advanced Research and Training in Scientific Calculus) was used, which is part of the Model Intercomparison Project Phase 6 (CMIP6). The CMIP6 integrates the new IPCC climate models.

For the construction of future models, the same Principal Components (PCs) and algorithms were used for the present models. Thus, climate change was projected for the periods 2041-2060, 2061-2080 and 20812100, considering two different scenarios of greenhouse gas (CO2) emissions: SSP245 (more optimistic, in which it is assumed that public policies will be adopted aiming at the mitigation of greenhouse gas emissions in the atmosphere) and SSP585 (more pessimistic, in which it is considered that no measure will be adopted to mitigate these effects) (SSP - Shared Socio-economic Pathways) (IPCC, 2021Intergovernmental Panel on Climate change - IPCC. Climate change 2021: the physical science basis. summary for policy makers. 2021. [citado 15 jun. 2021]. Disponível em: https://www.ipcc.ch/report/ar6/wg1/downloads/report/IPCCAR6WGIFullReport. pdf.Acesso
https://www.ipcc.ch/report/ar6/wg1/downl... ).

The occurrences of Conservation Units (CUs), Indigenous Lands (IL), and Ramsar Sites (RS) were analyzed for their strategic locations for the conservation effect of the species studied in the study. In the selection, Protected Areas (PAs) were considered those that contain environments of wetlands. The PAs with climatically suitable areas, but that did not present humid areas within their limits, were not considered. In addition, CUs and ILs located within RS, were analyzed as areas of RS. And CUs, which overlapped with IL, were calculated as IL areas.

The layers of vector files in shapefile format containing the limits of CUs and IL were obtained on the TerraBrasilis platform, of the National Institute of Space Research (INPE, 2022Instituto Nacional de Pesquisas Espaciais - INPE. Coordenação geral de observação da terra. Programa de Monitoramento da Amazônia e demais biomas. Desmatamento - Amazônia Legal. 2022. [citado 05 jan. 2022]. Disponível em: http://terrabrasilis.dpi.inpe.br/downloads/
http://terrabrasilis.dpi.inpe.br/downloa... ). Information about the RS Sites was obtained on the Ramsar Sites Information Service platform.

3. RESULTS

Of the 19 main components generated in the PCA, the first six were used in the modeling process of the species, which together represented about 97% of the total variability of the data. The axes that best explained the variation were observed in the first and second PCs, representing, respectively, 56% and 20% of the total variability of the database.

In PC1, the three most important climatic variables, with higher eigenvector values, were related to air temperatures: minimum temperature in the coldest month (Bio6), average temperature in the coldest quarter (Bio11), and average temperature in the driest quarter (Bio9). In PC2, the most representative variables were related to precipitation: rainfall accumulated in the driest month (Bio14); rainfall accumulated in the driest quarter (Bio17), and rainfall seasonality (Bio15) (Table 1).

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Table 1
Eigenvector values of the six main components (PC) used in the modeling process.
Tabela 1
Valores de autovetores dos seis Componentes Principais (PC) utilizados no processo de modelagem.

The five algorithms used produced satisfactory results for the species and metrics tested, showing evaluation rates greater than 0.7 (Table 2). Regarding the difference between the evaluative metrics, the AUC stood out with the highest values ranging from 0.91 to 0.99, while the results of the TSS model ranged from 0.72 to 0.94.

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Table 2
Evaluation of the algorithms used in the modeling process of the species Alchornea castaneifolia and Laetia corymbulosa of low floodplain (LF) and Maquira coriacea and Ocotea cymbarum of high floodplain (HF)
Tabela 2
Avaliação dos algoritmos utilizados no processo de modelagem das espécies Alchornea castaneifolia e Laetia corymbulosa de várzea baixa (LF) e Maquira coriacea e Ocotea cymbarum de várzea alta (HF)

The consensus model shows that for current climate conditions, the lowland floodplain species A. castaneifolia was the one that presented the largest area of climatic adequacy with approximately 7,919,331 km², where 54.36% of this area is concentrated in the region of the Amazon basin but also presents favorable areas in the Cerrado, Pantanal, Caatinga, and Atlantic Forest (Figure 2A). Although the species is limited to floodable environments, A. castaneifolia (LF) proved to be adaptable to different conditions, being able to establish itself in different Brazilian phytogeographic domains, except for the Pampa. The remaining species were limited to the Amazon basin.

Due to the endemism of the Amazon floodplains, the species L. corymbulosa (LF) (Figure 2B) presented the smallest modeled area, with 4,592,537 km², approximately 59.11% of the Brazilian Amazon area. The two HL species presented in this study have similar climatic suitability areas (Figures 2C and 2D). The species M. coriacea was presented in an area of 7,010,489 km², while for O. cymbarum it was approximately 5,736,946 km².

The projections of the consensus models for the SSP 245 scenario indicate an increase of about 30% in the climatic adequacy areas of A. castaneifolia (LF) for the three periods analyzed (Figure 3). In this scenario, A. castaneifolia (LF) showed a significant increase in the distribution area in the Brazilian phytogeographic domains of the Atlantic Forest (+125%), Caatinga (+102%), and Cerrado (+58%).

Figure 3
Maps of climatic suitability under the scenarios SSP 245 and SSP 585 for the years 2041-2060, 2061-2080 and 2081-2100.
Figura 3
Mapas de adequabilidade climática sob os cenários SSP 245 e SSP 585 para os anos de 2041-2060, 2061-2080 e 2081-2100.

For the species L. corymbulosa (LF) and O. cymbarum (HF), the models of SSP 245 estimate a similar behavior, showing an increase in the distribution area in the scenarios for the periods of 2041-2060, of 7% and 4%, respectively. However, in the periods 20612080 and 2081-2100, the model showed a loss of favorable areas in relation to the present period. In 2081-2100, for L. corymbulosa, the loss would be 6% and for O. cymbarum, 8% (Figure 3; Table 3).

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Table 3
Projections of increase or loss of climate adequacy area (%) in scenarios SSP245 and SSP585 for the three evaluation periods compared to the current period, in South America
Tabela 3
Projeções de acréscimo ou perda de área de adequação climática (%) nos cenários SSP245 e SSP585 para os três períodos de avaliação em comparação com o período atual na América do Sul

For M. coriacea (HF), there was an increase in the distribution areas in the scenario SSP 245 (1%) for the periods 2041-2060 and 2061-2080. The SSP 585 scenario showed projections with a greater decline of the areas of climatic adequacy for the species during the three periods analyzed, with the lowest loss of favorable area (-16%) for A. castaneifolia (LF) in the period 2081-2100 (Table 3). The species L. corymbulosa (HF) and O. cymbarum (LF) showed losses of approximately 61% from 2061-2080 in scenario SSP 585, and in a more critical scenario from 2081-2100, they experienced a reduction in areas of approximately 91%. For M. coriacea (HF), the models indicated losses of 10% in 20612080 and 78% between 2081-2100 (Table 3).

4. DISCUSSION

Although the scenario SSP-585 is considered more extreme, studies indicate that this has become more realistic (homologous to RCP 85 of the 5th IPCC evaluation report), given the current emissions of greenhouse gases (Schwalm et al., 2020Schwalm CR, Glendon S, Duffy PB. RCP8. 5 tracks cumulative CO2 emissions. Proceedings of the National Academy of Sciences. 2020;117(33):19656-19657. doi: https://doi.org/10.1073/pnas.2007117117
https://doi.org/10.1073/pnas.2007117117... ). The results indicate that climate change will pose threats to the occurrence of Amazon floodplain species, especially in the SSP-585 scenario. The species M. coriacea (LF) has pioneer characteristics, including high amplitude of dispersion and rapid growth, being able to germinate and establish itself in large clearings and open areas, and tolerating more hostile environments with high irradiance, high temperature, and low humidity of air and soil (Nebel, 2000Nebel G. Arbol de la llanura aluvial amazónica Maquira coriacea (Karsten) CC Berg: aspectos de ecología y manejo. Folia Amazónica. 2000;11(1-2):5-29. doi: https://doi.org/10.24841/fa.v11i1-2.113
https://doi.org/10.24841/fa.v11i1-2.113... ).

The species O. cymbarum has dispersion at short distances, grows slower, and establishes itself in the shade, not tolerating adverse conditions (Wittmann et al., 2009Wittmann F, Schöngart J, Queiroz HL, Wittmann ADO, Conserva ADS, Piedade MT, Kesselmeier J, Junk WJ. The Amazon floodplain Demonstration Site: Sustainable timber production and management of Central Amazonian white-water floodplains. Ecohydrology & Hydrobiology. 2009;9(1):4154. doi: https://doi.org/10.2478/v10104-0090038-4
https://doi.org/10.2478/v10104-0090038-4... ). The results obtained for LF species are consistent, with higher reported area losses for O. cymbarum, as it is considered less resistant compared to M. coriacea in the aspects of growth, dispersion, and shading tolerance, which are relevant for adaptation.

The HF species, A. castaneifolia and L. corymbulosa, do not germinate on dry land or in the absence of humidity (Wittmann et al., 2006Wittmann F, Schöngart J, Montero JC, Motzer T, Junk WJF, Piedade MT, Queiroz HL, Worbes M. Tree species composition and diversity gradients in white-water forests across the Amazon Basin. Journal of Biogeography. 2006;33(8):1334-1347. doi: https://doi.org/10.1111/j.1365-2699.2006.01495.x
https://doi.org/10.1111/j.1365-2699.2006... ). The pioneer species, A. castaneifolia was the only species to show areas of adaptation in almost all scenarios, except for the period 2081-2100 of SSP 585, possibly because it is not endemic to the Amazon.

Despite this, significant gains in area occurred in the phytogeographic domains of the Cerrado, Caatinga, and Atlantic Forest. However, in the 2081-2100 scenario of SSP 585, the species would remain within about 60% of suitable areas in the Amazon, especially, in the southern region of the basin. The losses would be precisely in the central region, with most of their points of occurrence in the region of extension of a floodplain. The results of the projections of the species studied also varied according to the study by Cordeiro et al. (2023)Cordeiro AL, Tomaz JS, Bezerra CS, Meneses CHSG, Aguiar AV, Wrege MS, Ramos SLF, Fraxe TJP, Lopes MTG. Prediction of the geographic distribution and conservation of Amazonian Palm trees Astrocaryum acaule MART. and Astrocaryum aculeatum MART. Revista Árvore. 2023;47:e4719. doi: https://doi.org/10.1590/1806-908820230000019
https://doi.org/10.1590/1806-90882023000... .

In the present period, the areas of climatic suitability for all species are predominantly in the Central, Northern, and Western Amazon regions, totaling 1,976,398 km² (Figure 4A). Of this area, 27% in CUs, 24% in IL, and 4% in RS. The current suitability area comprises around 62% (or 271,074 km²) of the humid areas of the Brazilian Amazon, and just over half (around 32% or 139,909 km²) is under some category of protection: 17% in CUs, 8 % in IL and 7% in RS.

Figure 4
A) Areas of high climatic adequacy in Amazon Protected Areas (present); B) Areas of high climatic adequacy in Amazon Protected Areas (2061-2080).
Figura 4
A) Áreas de adequação climática em Áreas Protegidas da Amazônia (presente); B) Áreas de adequação climática em Áreas Protegidas da Amazônia (2061-2080).

The estimates for the years 2061-2080 presented in Figure 4B, show an area of climatic suitability with extending around 427,599 km² totaling a loss of 78% concerning the present. In addition, of the total area estimated by the model (427,599 km²), around 307,705 km² (60%) would be in PAs: 27% in tis; 25% in CUs, and 8% in RS. Regarding wetlands, only 14% (about 60,336 km²) would be in areas of climatic suitability, and only 7% (32,222 km²) would be in PAs, 3% in RS, 3%, in UCs, and 1% in IL.

In total, 61 PAs would remain with areas of climatic suitability in the future projection. The most representative are the Yanomami Indigenous Land (TIY) with 63,429 km² and the Ramsar Regional Site of the Rio Negro with 27,401 km², both in the Rio Negro Basin; the Cujubim Sustainable Development Reserve with 15,216 km², the Javari Valley Indigenous Land with 14,343 km² and the Ramsar Regional Site of the Juruá River with 9,649 km², all along the Solimões River Basin; and the State Forest of Trombetas with 9,781 km² located in the Amazon River basin. These PAs would comprise 30% of the total climate suitability areas (Figure 4B).

Currently, about 54% of the Brazilian Amazon is covered by some PA (CUs cover 28.6% and IL 25.42%) (MMA, 2022Ministério do Meio Ambiente - MMA. Cadastro Nacional de Unidades de Conservação. 2022. [citado 05 jan. 2022]. Disponível em: https://app.powerbi.com
https://app.powerbi.com... ). However, the results obtained in the present study indicate that the current configuration would not guarantee the conservation of floodplain species in the face of future climate change and the continuous growth of greenhouse gas emissions. These results are consistent with Anderson et al. (2019)Anderson EP, Osborne T, MaldonadoOcampo JA, Mills-Novoa M, Castello L, Montoya M, Encalada AC, Jenkins CN. Energy development reveals blind spots for ecosystem conservation in the Amazon Basin. Frontiers in Ecology and the Environment. 2019;17(9):521-529. doi:https://doi.org/10.1002/fee.2114
https://doi.org/10.1002/fee.2114... , who found that the Amazon AP network does not protect freshwater ecosystems against the risks associated with anthropogenic activities, such as the establishment of hydroelectric plants, deforestation, and pollution. Frederico et al. (2018)Frederico RG, Zuanon J, De Marco Junior P. Amazon protected areas and its ability to protect stream-dwelling fish fauna. Biological Conservation. 2018;219:12-19. doi: https://doi.org/10.1016/j.biocon.2017.12.032
https://doi.org/10.1016/j.biocon.2017.12... show that the composition of protected areas in the Amazon does not guarantee the protection of species of aquatic fauna in the region, such as fish and sea turtles.

These results show that most PAs have the predominant objective of protecting terrestrial ecosystems, failing to ensure the conservation of freshwater systems and, consequently, the environment of wetlands. It is necessary to delimit new conservation PAs in situ in the reported regions that will suffer less impact from climate change and to draw strategies for conserving the variability of species at risk of extinction, aiming at ex-situ conservation.

In Brazil, the guidelines adopted for the inclusion of RS require that such areas correspond to PAs, that is, they are equivalent to CUs or IL (MMA, 2022Ministério do Meio Ambiente - MMA. Cadastro Nacional de Unidades de Conservação. 2022. [citado 05 jan. 2022]. Disponível em: https://app.powerbi.com
https://app.powerbi.com... ). In a study on land use in the Brazilian RS, Ribeiro et al. (2020)Ribeiro S, Moura RG, Stenert C, Florín M, Maltchik L. Land use in Brazilian continental wetland Ramsar sites. Land Use Policy. 2020;99:104851. doi: https://doi.org/10.1016/j.landusepol.2020.104851
https://doi.org/10.1016/j.landusepol.202... showed that the Amazonian RS are well preserved, presenting a low anthropic disturbance within their limits. However, there are only nine RS in the Amazon, covering 79,373 km² (Anderson et al., 2019Anderson EP, Osborne T, MaldonadoOcampo JA, Mills-Novoa M, Castello L, Montoya M, Encalada AC, Jenkins CN. Energy development reveals blind spots for ecosystem conservation in the Amazon Basin. Frontiers in Ecology and the Environment. 2019;17(9):521-529. doi:https://doi.org/10.1002/fee.2114
https://doi.org/10.1002/fee.2114... ), or only 18% of the wetlands of the Brazilian Amazon, which have an estimated area of 437,216 km² (Hess et al., 2015Hess LL, Melack JM, Affonso AG, Barbosa C, Gastil-Buhl M, Novo EM. Wetlands of the lowland Amazon basin: Extent, vegetative cover, and dual-season inundated area as mapped with JERS-1 synthetic aperture radar. Wetlands. 2015;35(4):745-756. doi: https://doi.org/10.1007/s13157-015-0666-y
https://doi.org/10.1007/s13157-015-0666-... ).

In the future climate scenario, the areas of climatic suitability overlap, mainly along the sub-basins of the Rio Negro and Rio Solimões (Figure 5). The two regions are relatively well preserved, given the presence of the Ramsar Regional Site of Rio Negro and the Ramsar Regional Site of Rio Juruá (Ribeiro et al., 2020Ribeiro S, Moura RG, Stenert C, Florín M, Maltchik L. Land use in Brazilian continental wetland Ramsar sites. Land Use Policy. 2020;99:104851. doi: https://doi.org/10.1016/j.landusepol.2020.104851
https://doi.org/10.1016/j.landusepol.202... ). Moreover, the two RS do not cover the entire extent of the areas suitable for species, from the climatic point of view, nor the entire extent of wetlands in the region. Furthermore, the flooded forests of the Rio Negro Basin are predominantly formed by areas of igapó, which limits the presence of specific species of floodplain, such as L. corymbulosa (Lobo et al., 2019Lobo GS, Wittmann F, Piedade MT. Response of black-water floodplain (igapó) forests to flood pulse regulation in a dammed Amazonian River. Forest Ecology and Management. 2019;434:110-118. doi: https://doi.org/10.1016/j.foreco.2018.12.001
https://doi.org/10.1016/j.foreco.2018.12... ).

Figure 5
Priority areas for the conservation of species.
Figura 5
Áreas prioritárias para a conservação das espécies.

There are overlapping areas in the central region (in the sub-basins of the Amazon River, Madeira, and Tapajós), but to a lesser extent in the eastern coastal region of the Brazilian Amazon (Figure 5). The Central region presents a mosaic of PAs of the Amazon. Nevertheless, its management approaches and conservation measures have a terrestrial bias, not presenting planning for the protection of humid environments. The Madeira River SubBasin comprises a large part of the wetlands of the entire Amazon (about 30%) (Hess et al., 2015Hess LL, Melack JM, Affonso AG, Barbosa C, Gastil-Buhl M, Novo EM. Wetlands of the lowland Amazon basin: Extent, vegetative cover, and dual-season inundated area as mapped with JERS-1 synthetic aperture radar. Wetlands. 2015;35(4):745-756. doi: https://doi.org/10.1007/s13157-015-0666-y
https://doi.org/10.1007/s13157-015-0666-... ). It should also be noted that the region does not have any designated area for the conservation of this type of ecosystem.

In recent years, human actions in the eastern and southern regions of the Amazon have intensified, such as deforestation, mining, and the implementation of hydroelectric projects (Evangelista-Vale et al., 2021Evangelista-Vale JC, Weihs M, JoséSilva L, Arruda R, Sander NL, Gomides SC, Machado TM, Pires-Oliveira JC, Barros-Rosa L, Castuera-Oliveira L, Matias RAM, Martins-Oliveira AT, Bernardo CSS, Silva-Pereira I, Carnicer C, Carpanedo RS, Eisenlohr PV. Climate change may affect the future of extractivism in the Brazilian Amazon. Biological Conservation. 2021;257:109093. doi: https://doi.org/10.1016/j.biocon.2021.109093
https://doi.org/10.1016/j.biocon.2021.10... ). These anthropic actions, in addition to increasing pressure on wetlands, potentiate climate change. This scenario puts at risk the PAs and biodiversity of the Amazon, in addition to weakening the conservation status of RS (Ribeiro et al., 2020Ribeiro S, Moura RG, Stenert C, Florín M, Maltchik L. Land use in Brazilian continental wetland Ramsar sites. Land Use Policy. 2020;99:104851. doi: https://doi.org/10.1016/j.landusepol.2020.104851
https://doi.org/10.1016/j.landusepol.202... ).

The adoption of more inclusive strategies, merging land and water conservation demands, is necessary to improve the effectiveness of Amazon’s network of PAs, changing the current focus, which is concentrated on dryland forests, to also cover freshwater ecosystems in the basin. It is important to expand the current protected areas, such as the reserves of the Negro and Juruá rivers, to encompass more wetlands in these regions. Additionally, new reserves should be established in key locations such as the sub-basins of the Amazon, Madeira, and Tapajós rivers, which are areas with a high concentration of wetlands (Hess et al., 2015Hess LL, Melack JM, Affonso AG, Barbosa C, Gastil-Buhl M, Novo EM. Wetlands of the lowland Amazon basin: Extent, vegetative cover, and dual-season inundated area as mapped with JERS-1 synthetic aperture radar. Wetlands. 2015;35(4):745-756. doi: https://doi.org/10.1007/s13157-015-0666-y
https://doi.org/10.1007/s13157-015-0666-... ).

5. CONCLUSION

The species Alchornea castaneifolia (LF), Laetia corymbulosa (LF), Maquira coriacea (HF), and Ocotea cymbarum (HF) appear predominantly in the Amazon Basin, and according to future projections, areas of occurrence will become vulnerable to the effects of climate change in the coming decades in the event of the SSP 585 scenario.

Among the four species studied, L. corymbulosa, O. cymbarum, and M. coriacea are the most threatened in future scenarios of climate change by the variable’s temperature, precipitation, and rainfall seasonality.

The current configuration of the Protected Areas (PAs) of the Brazilian Amazon does not guarantee the conservation of the species studied in the face of future climate changes.

The implementation of conservation measures should be treated as a priority in the regions of the Ramsar Regional Sites of the Rio Negro, the Juruá River, the Yanomami Indigenous Lands and the Javari Valley, the Cujubim Sustainable Development Reserve, and the Trombetas State Forest.

The regions conserved in PAs, along the sub-basins of the Amazon, Madeira, and Tapajós rivers, are presented as strategic points for the implementation of new priority areas for the conservation of these environments.

6. ACKNOWLEDGEMENTS

The authors thank for funding the study by Coordination for the Improvement of Higher Education Personnel -Brazil (CAPES)- Edital nº 16/2020 - PROCAD-SPCF and by the National Council for Scientific and Technological Development, process number- 442914/2020-2.

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Publication Dates

Publication in this collection
14 June 2024
Date of issue
2024

History

Received
29 Dec 2023
Accepted
20 Mar 2024

This is an Open Access article distributed under the terms of the Creative Commons Attribution License, which permits unrestricted use, distribution, and reproduction in any medium, provided the original work is properly cited.

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Variables	PC1	PC2	PC3	PC4	PC5	PC6
Bio1	-0.2707	-0.2257	0.1302	-0.0462	0.0612	0.0022
Bio2	0.1767	-0.2413	0.1159	0.4889	-0.1291	0.5284
Bio3	-0.2378	-0.0120	-0.3183	0.1014	0.2300	0.5198
Bio4	0.2489	0.0078	0.3866	-0.0643	-0.2282	-0.0908
Bio5	-0.1927	-0.3193	0.3409	-0.0384	-0.1331	0.0694
Bio6	-0.2940	-0.1193	-0.0036	-0.1567	0.0890	-0.0169
Bio7	0.2492	-0.1248	0.3247	0.1931	-0.2547	0.0897
Bio8	-0.2334	-0.2547	0.2325	0.0629	0.1127	-0.0032
Bio9	-0.2765	-0.1545	-0.0162	-0.1722	0.0048	0.0252
Bio10	-0.2304	-0.2633	0.3052	-0.1006	-0.0318	-0.0260
Bio11	-0.2858	-0.1827	0.0033	-0.0302	0.1026	0.0274
Bio12	-0.2630	0.2206	0.0386	0.1832	-0.1994	-0.0609
Bio13	-0.2692	0.0792	-0.1161	0.2335	-0.3329	-0.2086
Bio14	-0.1442	0.3955	0.2416	0.0341	0.1130	0.3041
Bio15	0.0331	-0.3381	-0.4061	0.3321	-0.1420	0.0019
Bio16	-0.2698	0.0876	-0.1038	0.2389	-0.3300	-0.2091
Bio17	-0.1551	0.3949	0.2323	0.0355	0.0830	0.2766
Bio18	-0.1602	0.1883	0.2022	0.5774	0.3222	-0.3318
Bio19	-0.1991	0.2068	-0.0761	-0.2126	-0.5974	0.2389

Algorithm	AUC TSS Jaccard			Sorensen
	Alchornea castaneifolia (LF)
BIO	0.95 (0.03)	0.91 (0.06)	0.91 (0.06)	0.95 (0.04)
DOM	0.93 (0.03)	0.74 (0.07)	0.76 (0.06)	0.86 (0.04)
MXS	0.93 (0.02)	0.78 (0.05)	0.81 (0.04)	0.89 (0.02)
RDF	0.99 (0.01)	0.94 (0.05)	0.94 (0.05)	0.97 (0.03)
SVM	0.98 (0.01)	0.88 (0.03)	0.89 (0.03)	0.94 (0.01)
		Laeta corymbulosa (LF)
BIO	0.94 (0.06)	0.87 (0.12)	0.87 (0.12)	0.93 (0.07)
DOM	0.95 (0.03)	0.83 (0.05)	0.85 (0.04)	0.92 (0.02)
MXS	0.98 (0.03)	0.93 (0.06)	0.93 (0.06)	0.96 (0.03)
RDF	0.99 (0.01)	0.93 (0.03)	0.93 (0.03)	0.96 (0.02)
SVM	0.98 (0.01)	0.88 (0.07)	0.90 (0.06)	0.94 (0.03)
		Maquira coriacea (HF)
BIO	0.96 (0.03)	0.91 (0.06)	0.91 (0.06)	0.95 (0.03)
DOM	0.92 (0.01)	0.72 (0.06)	0.76 (0.05)	0.86 (0.03)
MXS	0.97 (0.01)	0,83 (0.05)	0.85 (0.03)	0.92 (0.02)
RDF	0.99 (0.01)	0.94 (0.06)	0.95 (0.05)	0.97 (0.03)
SVM	0.97 (0.02)	0.89 (0.06)	0.90 (0.06)	0.94 (0.04)
		Ocotea cymbarum (HF)
BIO	0.95 (0.04)	0.90 (0.07)	0.90 (0.07)	0.95 (0.04)
DOM	0.91 (0.04)	0.72 (0.09)	0.77 (0.06)	0.87 (0.04)
MXS	0.93 (0.03)	0.84 (0.06)	0.86 (0.05)	0.92 (0.03)
RDF	0.98 (0.02)	0.90 (0.03)	0.91 (0.03)	0.95 (0.02)
SVM	0.97 (0.01)	0,87 (0.03)	0.88 (0.03)	0.93 (0.02)

Species		SSP 245			SSP 585
Species	2041-2060	2061-2080	2081-2100	2041-2060	2061-2080	208-2100
AC	+27%	+29%	+30%	+28%	+23%	-16%
LC	+7%	+1%	-6%	-4%	-61%	-93%
MO	+1%	+1%	0	-1%	-10%	-78%
OC	+4%	0	-8%	-19%	-64%	-91%

Brasil

Brasil

IMPACTS OF CLIMATE CHANGE ON THE NATURAL DISTRIBUTION OF SPECIES OF LOWLAND HIGH AND LOW IN THE AMAZON

IMPACTOS DAS MUDANÇAS CLIMÁTICAS NA DISTRIBUIÇÃO NATURAL DE ESPÉCIES DE VÁRZEA ALTA E BAIXA NA AMAZÔNIA

ABSTRACT

RESUMO

1. INTRODUCTION

2. MATERIAL AND METHODS

3. RESULTS

4. DISCUSSION

5. CONCLUSION

6. ACKNOWLEDGEMENTS

7. REFERENCES

Publication Dates

History