Your search keyword '"Quesada, Carlos A."' showing total 3 results

1. Wood Nutrient-Water-Density Linkages Are Influenced by Both Species and Environment.

Author

Lira-Martins, Demetrius, Quesada, Carlos Alberto, Strekopytov, Stanislav, Humphreys-Williams, Emma, Herault, Bruno, and Lloyd, Jon

Subjects

WOOD, WOOD density, WATER storage, FOREST density, SPECIES

Abstract

Tropical trees store a large amount of nutrients in their woody tissues, thus triggering the question of what the functional association of these elements with other wood traits is. Given the osmotic activity of mineral elements such as potassium, sodium, and calcium, these elements should be strong candidates in mediating the water storing capacity in tropical trees. We investigated the role of wood nutrients in facilitating wood water storage in trees by using branch samples from 48 tropical tree species in South America and examined their associations with wood density (ρ). Wood density varied from 316 kg/m3 in Peru plots, where the soil nutrient status is relatively higher, to 908 kg/m3 in Brazil plots, where the nutrient availability is lower. Phosphorus content in wood varied significantly between plots with lowest values found in French Guiana (1.2 mol/m3) and plots with highest values found in Peru (43.6 mol/m3). Conversely, potassium in woody tissues showed a significant cross-species variation with Minquartia guianensis in Brazil showing the lowest values (8.8 mol/m3) and with Neea divaricata in Peru having the highest values (114 mol/m3). We found that lower wood density trees store more water in their woody tissues with cations, especially potassium, having a positive association with water storage. Specific relationships between wood cation concentrations and stem water storage potential nevertheless depend on both species' identity and growing location. Tropical trees with increased water storage capacity show lower wood density and have an increased reliance on cations to regulate this reservoir. Our study highlights that cations play a more important role in tropical tree water relations than has previously been thought, with potassium being particularly important. [ABSTRACT FROM AUTHOR]

Published

2022

2. Leaf-level photosynthetic capacity in lowland Amazonian and high-elevation Andean tropical moist forests of Peru.

Author

Bahar, Nur H. A., Ishida, F. Yoko, Weerasinghe, Lasantha K., Guerrieri, Rossella, O'Sullivan, Odhran S., Bloomfield, Keith J., Asner, Gregory P., Martin, Roberta E., Lloyd, Jon, Malhi, Yadvinder, Phillips, Oliver L., Meir, Patrick, Salinas, Norma, Cosio, Eric G., Domingues, Tomas F., Quesada, Carlos A., Sinca, Felipe, Escudero Vega, Alberto, Zuloaga Ccorimanya, Paola P., and Aguila‐Pasquel, Jhon

Subjects

PHOTOSYNTHETIC rates, CARBOXYLATION, PHOTOSYNTHESIS, FORESTS & forestry

Abstract

We examined whether variations in photosynthetic capacity are linked to variations in the environment and/or associated leaf traits for tropical moist forests ( TMFs) in the Andes/western Amazon regions of Peru., We compared photosynthetic capacity (maximal rate of carboxylation of Rubisco ( Vcmax), and the maximum rate of electron transport ( Jmax)), leaf mass, nitrogen (N) and phosphorus (P) per unit leaf area ( Ma, Na and Pa, respectively), and chlorophyll from 210 species at 18 field sites along a 3300-m elevation gradient. Western blots were used to quantify the abundance of the CO2-fixing enzyme Rubisco., Area- and N-based rates of photosynthetic capacity at 25°C were higher in upland than lowland TMFs, underpinned by greater investment of N in photosynthesis in high-elevation trees. Soil [P] and leaf Pa were key explanatory factors for models of area-based Vcmax and Jmax but did not account for variations in photosynthetic N-use efficiency. At any given Na and Pa, the fraction of N allocated to photosynthesis was higher in upland than lowland species. For a small subset of lowland TMF trees examined, a substantial fraction of Rubisco was inactive., These results highlight the importance of soil- and leaf-P in defining the photosynthetic capacity of TMFs, with variations in N allocation and Rubisco activation state further influencing photosynthetic rates and N-use efficiency of these critically important forests. [ABSTRACT FROM AUTHOR]

Published

2017

3. The productivity, metabolism and carbon cycle of two lowland tropical forest plots in south-western Amazonia, Peru.

Author

Malhi, Yadvinder, Farfán Amézquita, Filio, Doughty, Christopher E., Silva-Espejo, Javier E., Girardin, Cécile A.J., Metcalfe, Daniel B., Aragão, Luiz E.O.C., Huaraca-Quispe, Lidia P., Alzamora-Taype, Ivonne, Eguiluz-Mora, Luzmilla, Marthews, Toby R., Halladay, Kate, Quesada, Carlos A., Robertson, Amanda L., Fisher, Joshua B., Zaragoza-Castells, Joana, Rojas-Villagra, Clara M., Pelaez-Tapia, Yulina, Salinas, Norma, and Meir, Patrick

Subjects

FOREST productivity, PLANT metabolism, CARBON cycle, CLIMATE change, SOIL respiration, HERBIVORES

Abstract

Background:The forests of western Amazonia are known to be more dynamic that the better-studied forests of eastern Amazonia, but there has been no comprehensive description of the carbon cycle of a western Amazonian forest. Aims:We present the carbon budget of two forest plots in Tambopata in south-eastern Peru, western Amazonia. In particular, we present, for the first time, the seasonal variation in the detailed carbon budget of a tropical forest. Methods:We measured the major components of net primary production (NPP) and total autotrophic respiration over 3–6 years. Results:The NPP for the two plots was 15.1 ± 0.8 and 14.2 ± 1.0 Mg C ha−1year−1, the gross primary productivity (GPP) was 35.5 ± 3.6 and 34.5 ± 3.5 Mg C ha−1year−1, and the carbon use efficiency (CUE) was 0.42 ± 0.05 and 0.41 ± 0.05. NPP and CUE showed a large degree of seasonality. Conclusions:The two plots were similar in carbon cycling characteristics despite the different soils, the most notable difference being high allocation of NPP to canopy and low allocation to fine roots in the Holocene floodplain plot. The timing of the minima in the wet–dry transition suggests they are driven by phenological rhythms rather than being driven directly by water stress. When compared with results from forests on infertile forests in humid lowland eastern Amazonia, the plots have slightly higher GPP, but similar patterns of CUE and carbon allocation. [ABSTRACT FROM PUBLISHER]

Published

2014