Your search keyword '"R. Q. Paiva"' showing total 2 results

1. Basin-wide variations in Amazon forest structure and function are mediated by both soils and climate

Author

Almut Arneth, A. Peña Cruz, E. M. Jimenez, Adriana Prieto, M. C. Peñuela, N. Priante Filho, S. Almeida, Ima Célia Guimarães Vieira, Carlos A. Quesada, Flávio J. Luizão, Yadvinder Malhi, A. J. B. Santos, Claudia I. Czimczik, Kuo-Jung Chao, John Terborgh, Armando Torres Lezama, J. Schmerler, P. Núñez Vargas, G. Lloyd, N. Dezzeo, Timothy R. Baker, Martin G. Hodnett, Julie Peacock, Agustín Rudas, E. Alvarez Dávila, David A. Neill, R. Vásquez, Timothy J. Killeen, Rafael de Paiva Salomão, Marcos Silveira, Nikolaos M. Fyllas, R. Q. Paiva, Sandra Patiño, A. Di Fiore, Niro Higuchi, Abel Monteagudo, Oliver L. Phillips, Luzmila Arroyo, Terry L. Erwin, Jon Lloyd, Nelson R.F.A. Silva, Michael P. Schwarz, Hirma Ramírez, Nigel C. A. Pitman, Rafael Herrera, Gabriela Lopez-Gonzalez, and E.N. Honorio Coronado

Subjects

Soil test, Phytomass, lcsh:Life, wood specific-gravity, Soil Chemistry, complex mixtures, Ecology and Environment, Meteorology and Climatology, Growth Rate, lcsh:QH540-549.5, Forest ecology, Physical Sciences and Mathematics, ddc:550, net primary productivity, Time-scale, Ecology, Evolution, Behavior and Systematics, Amazon Basin, Earth-Surface Processes, Forest floor, Soil Fertility, Forest dynamics, branch xylem density, Ecology, Soil Quality, lcsh:QE1-996.5, Soil chemistry, Phosphorus, Edaphic, use efficiency, stem water storage, Soil quality, long term plots, tropical rain-forest, Ion Exchange, lcsh:Geology, geographical ecology, lcsh:QH501-531, Earth sciences, plant-growth responses, Agriculture and Soil Science, Forest Dynamics, Potassium, ecological field experiments, lcsh:Ecology, Soil fertility

Abstract

Forest structure and dynamics vary across the Amazon Basin in an east-west gradient coincident with variations in soil fertility and geology. This has resulted in the hypothesis that soil fertility may play an important role in explaining Basin-wide variations in forest biomass, growth and stem turnover rates. Soil samples were collected in a total of 59 different forest plots across the Amazon Basin and analysed for exchangeable cations, carbon, nitrogen and pH, with several phosphorus fractions of likely different plant availability also quantified. Physical properties were additionally examined and an index of soil physical quality developed. Bivariate relationships of soil and climatic properties with above-ground wood productivity, stand-level tree turnover rates, above-ground wood biomass and wood density were first examined with multivariate regression models then applied. Both forms of analysis were undertaken with and without considerations regarding the underlying spatial structure of the dataset. Despite the presence of autocorrelated spatial structures complicating many analyses, forest structure and dynamics were found to be strongly and quantitatively related to edaphic as well as climatic conditions. Basin-wide differences in stand-level turnover rates are mostly influenced by soil physical properties with variations in rates of coarse wood production mostly related to soil phosphorus status. Total soil P was a better predictor of wood production rates than any of the fractionated organic- or inorganic-P pools. This suggests that it is not only the immediately available P forms, but probably the entire soil phosphorus pool that is interacting with forest growth on longer timescales. A role for soil potassium in modulating Amazon forest dynamics through its effects on stand-level wood density was also detected. Taking this into account, otherwise enigmatic variations in stand-level biomass across the Basin were then accounted for through the interacting effects of soil physical and chemical properties with climate. A hypothesis of self-maintaining forest dynamic feedback mechanisms initiated by edaphic conditions is proposed. It is further suggested that this is a major factor determining endogenous disturbance levels, species composition, and forest productivity across the Amazon Basin.

Published

2012

2. Optimisation of photosynthetic carbon gain and within-canopy gradients of associated foliar traits for Amazon forest trees

Author

Sandra Patiño, Lina M. Mercado, Gabriela Bielefeld Nardoto, Ines Hilke, Timothy R. Baker, Michael Raessler, Luiz Antonio Martinelli, A. J. B. Santos, Jon Lloyd, Carlos A. Quesada, H. Gielmann, Flávio J. Luizão, R. Q. Paiva, and Willi A. Brand

Subjects

Canopy, δ13C, AMAX, lcsh:QE1-996.5, lcsh:Life, Atmospheric sciences, Photosynthesis, Photosynthetic capacity, lcsh:Geology, lcsh:QH501-531, Dry weight, lcsh:QH540-549.5, Botany, lcsh:Ecology, Literature survey, Ecology, Evolution, Behavior and Systematics, Earth-Surface Processes, Mathematics, Woody plant

Abstract

Vertical profiles in leaf mass per unit leaf area (MA), foliar 13C composition (δ13C), nitrogen (N), phosphorus (P), carbon (C) and major cation concentrations were estimated for 204 rain forest trees growing in 57 sites across the Amazon Basin. Data was analysed using a multilevel modelling approach, allowing a separation of gradients within individual tree canopies (within-tree gradients) as opposed to stand level gradients occurring because of systematic differences occurring between different trees of different heights (between-tree gradients). Significant positive within-tree gradients (i.e. increasing values with increasing sampling height) were observed for MA and [C]DW (the subscript denoting on a dry weight basis) with negative within-tree gradients observed for δ13C, [Mg]DW and [K]DW. No significant within-tree gradients were observed for [N]DW, [P]DW or [Ca]DW. The magnitudes of between-tree gradients were not significantly different to the within-tree gradients for MA, δ13C, [C]DW, [K]DW, [N]DW, [P]DW and [Ca]DW. But for [Mg]DW, although there was no systematic difference observed between trees of different heights, strongly negative within-tree gradients were found to occur. When expressed on a leaf area basis (denoted by the subscript "A"), significant positive gradients were observed for [N]A, [P]A and [K]A both within and between trees, these being attributable to the positive intra- and between-tree gradients in MA mentioned above. No systematic within-tree gradient was observed for either [Ca]A or [Mg]A, but with a significant positive gradient observed for [Mg]A between trees (i.e. with taller trees tending to have a higher Mg per unit leaf area). Significant differences in within-tree gradients between individuals were observed only for MA, δ13C and [P] A. This was best associated with the overall average [P]A for each tree, this also being considered to be a surrogate for a tree's average leaf area based photosynthetic capacity, Amax. A new model is presented which is in agreement with the above observations. The model predicts that trees characterised by a low upper canopy Amax should have shallow, or even non-existent, within-canopy gradients in Amax, with optimal intra-canopy gradients becoming sharper as a tree's upper canopy Amax increases. Nevertheless, in all cases it is predicted that the optimal within-canopy gradient in Amax should be substantially less than for photon irradiance. Although this is also shown to be consistent with numerous observations as illustrated by a literature survey of gradients in photosynthetic capacity for broadleaf trees, it is also in contrast to previously held notions of optimality. A new equation relating gradients in photosynthetic capacity within broadleaf tree canopies to the photosynthetic capacity of their upper canopy leaves is presented.

Published

2010