Las Sabanas Pueden Convertirse Funcionalmente en Bosques en la Transición Amazonas/Cerrado

Autores/as

  • Marco Bruno Xavier Valadão Programa de Pós-Graduação em Ciências Florestais/UnB – Universidade de Brasília
  • Karla Monique Silva Carneiro Programa de Pós-Graduação em Ecologia e Conservação/UNEMAT
  • Ben Hur Marimon Junior Programa de Pós-Graduação em Ecologia e Conservação/UNEMAT
  • Fabiana Piontekowski Ribeiro Programa de Pós-Graduação em Ciências Florestais/UnB – Universidade de Brasília
  • Beatriz Schwantes Marimon Programa de Pós-Graduação em Ecologia e Conservação/UNEMAT

DOI:

https://doi.org/10.37002/biodiversidadebrasileira.v11i3.1764

Palabras clave:

Cerradão (Bosque de la Sabana) , Sabana densa , Marimon-Hay, constante de descomposición k, malla de la raíz

Resumen

Las formaciones forestales adyacentes son zonas de ecotono que pueden revelarcambios en la estructura vertical de biomas tropicales, por ejemplo, en el Cerrado (Sabana brasileña). La producción de hojarasca es una métrica que refleja estas alteraciones. Así, investigamos los principales aspectos funcionales del Cerradão (Bosque de la Sabana) y Cerrado denso (Sabana densa) adyacentes en la transición Amazonas/Cerrado. Evaluamos la capa de hojarasca, la descomposición de las hojas y la malla de la raíz para verificar hasta qué punto estos parámetros están relacionados con el funcionamiento del ecosistema de las dos formaciones diferentes, bosque y sabana. El sistema integrado de capa de hojarasca/malla de la raíz es la principal condición previa para el funcionamiento del ecosistema y el equilibrio trófico de los bosques tropicales en suelos distróficos. La capa de hojarasca, la malla de la raíz y las tasas de descomposición de las hojas fueron similares en ambos ecosistemas, incluindo la liberación de carbono de la capa de hojarasca, a pesar de las diferencias florísticas y estructurales en las vegetaciones. Estas similitudes indican una densificación de la sabana adyacente con una preestructuración del funcionamiento de un ecosistema de tipo forestal, principalmente debido a la exclusión del fuego. Esto sugiere que los ecosistemas de sabana en suelos distróficos en la transición Amazonas/Cerrado tienen un alto potencial para establecer condiciones tróficas funcionales para sostener una comunidad forestal en ausencia de incendios y cambios climáticos. Desde que el clima actual no cambie a condiciones más secas y cálidas (por ejemplo, un aumento de las anomalías de El Niño), la sucesión ecológica puede desencadenarse y las sabanas pueden convertirse funcionalmente en bosques, con un aumento de las reservas de carbono del ecosistema.

Citas

Andrade EM, Guerreiro MJS, Palácio HAQ, Campos DA. Ecohydrology in a Brazilian tropical dry forest: thinned vegetation impact on hydrological functions and ecosystem services, Journal of Hydrology: Regional Studies, 27(100649):1-13, 2020.

Barbosa RI, Silva SJR, Souza CM, Pimentel TP, Fearnside PM. Root biomass, root:shoot ratio and belowground carbon stocks in the open savannahs of Roraima, Brazilian Amazonia. Australian Journal of Botany, 60(5): 405-416, 2012.

Bocock KL, Gilbert OJ. The disappearance of litter under different woodland conditions. Plant Soil, 9: 179-185, 1957.

Brasil LS, Giehl NFS, Santos JO, Santos AO, Marimon BS, Marimon-Junior BH. Efeito de borda sobre a camada de serapilheira em área de Cerradão no leste de Mato Grosso. Biotemas, 37: 37-47, 2013.

Doughty EC, et al. Drought impact on forest carbon dynamics and fluxes in Amazonia. Nature, 519(7041): 78-82, 2015.

Empresa Brasileira de Pesquisa Agropecuária - EMBRAPA. 2018. Sistema brasileiro de classificação de solos. 5 ed. Embrapa. 356p.

Garcia AS et al. Assessing land use/cover dynamics and exploring drivers in the Amazon’s arc of deforestation through a hierarchical, multi-scale and multi-temporal classification approach. Remote Sensing Applications: Society and Environment, 15: 100233, 2019.

Franczak DD, Marimon BS, Marimon-Junior BH, Mews HA, Maracahipes L. Oliveira EA. Changes in the structure of a savanna forest over a six-year period in the Amazon-Cerrado transition, Mato Grosso state, Brazil. Rodriguésia, 62(2): 425-436, 2011.

Higuchi N, Santos J, Ribeiro RJ, Minette L, Biot Y. Biomassa da parte aérea da vegetação de floresta tropical úmida de terra firme da Amazônia Brasileira. Acta Amazon, 28(2): 153-165, 1998.

Hobbie SE. Plant species effects on nutrient cycling: revisiting litter feedbacks. Trends Ecology Evolution, 30(6): 357-363, 2015.

Hoffmann WA, Geiger EL, Gotsch SG, Rossato, DR, Silva LCR, Lau OL. Ecological thresholds at the savanna-forest boundary: how plant traits, resources and fire govern the distribution of tropical biomes. Ecology Letters, 15(7): 759-768, 2012a.

Hoffmann WA, Jaconis SY, Mckinley KL, Geiger EL, Gotsch SG, Franco AC. Fuels or microclimate? Understanding the drivers of fire feedbacks at savanna-forest boundaries. Austral Ecology, 37(6): 634-643, 2012b.

Hoffmann WA, Orthen B, Franco AC. Constraints to seedling success of savanna and forest trees across the savanna–forest boundary. Oecologia, Berlin, 140: 252-260, 2004.

Jacobson TKB, Bustamante MMC. 2014. Leaf litter decomposition and nutrient release under nitrogen, phosphorus and nitrogen plus phosphorus additions in a savanna in Central Brazil, p. 155-163. In: Sutton MA, Manso KE, Sheppard LJ, Sverdrup H, Haeuber R, Hicks, WK (eds.). Nitrogen deposition, critical loads and biodiversity. Springer Dordrecht. 535p.

Jobbágy EG, Jackson RB. The vertical distribution of soil organic carbon and its relation to climate and vegetation. Ecological Applications, 10(2): 423-436, 2000.

Malhi Y, Doughty C, Galbraith D. The allocation of ecosystem net primary productivity in tropical forests. Philosophical Transactions of the Royal Society B: Biological Sciences, 366: 3225-3245, 2011.

Marimon BS, et al. Disequilibrium and hyperdynamic tree turnover at the forest-cerrado transition zone in southern Amazonia. Plant Ecology Diversity, 7(1-2): 281-292, 2014.

Marimon-Junior BH, Haridasan M. Comparação da vegetação arbórea e características edáficas de um cerradão e um cerrado sensu stricto em áreas adjacentes sobre solo distrófico no leste de Mato Grosso, Brasil. Acta Botanica Brasilica, 19: 913-926, 2005.

Marimon-Junior BH, Hay JD. A new instrument and protocol for measurement and collection of quantitative samples of the litter layer in forests. Forest Ecology Management, 255(7): 2244-2250, 2008.

Marques EQ, Marimon-Junior BH, Matricardi EAT, Mews HA, Colli GR. Redefining the Cerrado-Amazonia transition: implications for conservation. Biodiversity and Conservation, 29: 501-1517, 2019.

Morandi OS, et al. Vegetation succession in the Cerrado-Amazonian forest transition zone of Mato Grosso state, Brazil. Edinburgh Journal of Botany, 73(1): 83-93, 2015.

Neves LFS, Marimon BS, Anderson LO, Neves SMAS. Dinâmica de fogo no parque estadual do Araguaia, zona de transição Amazônia-Cerrado. Raega - O Espaço Geográfico em Análise, 44: 85-103, 2018.

Oliveira B, Marimon-Junior BH, Mews HA, Valadão MBX, Marimon BS. Unraveling the ecosystem functions in the Amazonia-Cerrado transition: evidence of hyperdynamic nutrient cycling. Plant Ecology, 218(2): 225-239, 2017.

Oliveira, RS, et al. Deep root function in soil water dynamics in cerrado savannas of central Brazil. Functional Ecology, 19(4): 574-581, 2005.

Olson JS. Energy storage and the balance of producers and decomposers in ecological systems. Ecology 44(2): 322-332, 1963.

Passos FB, et al. Savanna turning into forest: concerted vegetation change at the ecotone between the Amazon and “Cerrado” biomes. Brazilian Journal of Botany, 41: 611-619, 2018.

Peixoto KS, et al. Assessing the effects of rainfall reduction on litterfall and the litter layer in phytophysiognomies of the Amazonia-Cerrado transition. Brazilian Journal of Botany, 41: 589-600, 2018.

Ratter JA, Richards PW, Argent G, Gifford DR. Observations on the vegetation of the northeastern Mato Grosso: I. The woody vegetation types of the Xavantina-Cachimbo Expedition area. Philosophical Transactions of the Royal Society of London B, 266: 449-492, 1973.

Ribeiro JF, Walter BMT. 1998. Fitofisionomias do Bioma Cerrado. p. 87-166. In: Sano SM, Almeida SP. (eds.). Cerrado: ambiente e flora. Brasília, Embrapa Cerrados. 556p.

Ribeiro JF, Walter BMT. 2008. As principais fitofisionomias do Bioma Cerrado. p.151-212. In: Sano SM, Almeida SP, Ribeiro JF (eds.). Cerrado: ecologia e flora. Planaltina, Embrapa. 406p.

Ribeiro FP, et al. Litter Dynamics in Eucalyptus and Native Forest in the Brazilian Cerrado. Journal of Agricultural Science, 10(11): 1-15, 2018.

Sayer EJ, Tanner EVJ, Cheesman AW. Increased litterfall changes fine root distribution in a moist tropical forest. Plant and Soil, 281(1-2): 5-13, 2006.

Silva FMA, Evangelista BA, Malaquias JV, Muller AG, Oliveira AD. 2017. Boletim de Pesquisa e Desenvolvimento 340: análise temporal de variáveis climáticas monitoradas entre 1974 e 2013 na Estação Principal da Embrapa. Embrapa Cerrados. 121p.

Sitch S, et al. Recent trends and drivers of regional sources and sinks of carbon dioxide. Biogeosciences 12(3): 653-679, 2015.

Sochacki SJ, Ritson P, Brand B, Harper RJ, Dell B. Accuracy of tree root biomass sampling methodologies for carbon mitigation projects. Ecological Engineering, 98: 264-274, 2017.

Souza JV, Ribeiro FC, Bussinguer, AP, Hodecker BER, Valadão MBX, Gatto A. Stock and litter decomposition in different vegetation types and eucalypt plantations in the Cerrado region, Brazil. Australian Journal of Basic and Applied Sciences 10(18): 74-81, 2016.

Speleta JFE, Clark, DA. Multi-scale variation in fine-root biomass in a Tropical Rain Forest: a seven-year study. Ecological Monographs, 77(3): 377-404, 2007.

Valadão MBX, Marimon-Junior BH, Oliveira B, Lucio NW, Souza MGR, Marimon BS. Biomass hyperdynamics as a key modulator of forest self-maintenance in a dystrophic soil in the Amazonia-Cerrado transition. Scientia Forestalis, 44(110): 475-485, 2016.

Vitousek PM, Sanford RL. Nutrient cycling in moist tropical forest. Annual Review of Ecology Systematics, 17: 137-167, 1986.

Xu X, Jia G, Zhang X, Riley WJ, Xue Y. Climate regime shift and forest loss amplify fire in Amazonian forests. Global Change Biology, 26(10): 5874-5885, 2020.

Zar JH. 2010. Biostatistical analysis. 5 ed. Prentice Hall. 718p.

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Publicado

03/11/2021

Número

Vol. 11 Núm. 3 (2021): Fluxo Contínuo

Sección

Fluxo contínuo

Licencia

Derechos de autor 2021 Biodiversidade Brasileira - BioBrasil

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