Your search keyword '"Keeling, Helen C."' showing total 3 results

1. 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

2. Contrasting patterns of diameter and biomass increment across tree functional groups in Amazonian forests.

Author

Keeling, Helen C., Baker, Timothy R., Martinez, Rodolfo Vasquez, Monteagudo, Abel, and Phillips, Oliver L.

Subjects

*BIOMASS, *TREES, *FORESTS & forestry, *PHOTOSYNTHESIS, *CARBON

Abstract

Species’ functional traits may help determine rates of carbon gain, with physiological and morphological trade-offs relating to shade tolerance affecting photosynthetic capacity and carbon allocation strategies. However, few studies have examined these trade-offs from the perspective of whole-plant biomass gain of adult trees. We compared tree-level annual diameter increments and annual above-ground biomass (AGB) increments in eight long-term plots in hyper-diverse northwest Amazonia to wood density (ρ; a proxy for shade tolerance), whilst also controlling for resource supply (light and soil fertility). ρ and annual diameter increment were negatively related, confirming expected differences in allocation associated with shade tolerance, such that light-demanding species allocate a greater proportion of carbon to diameter gain at the expense of woody tissue density. However, contrary to expectations, we found a positive relationship between ρ and annual AGB increment in more fertile sites, although AGB gain did not differ significantly with ρ class on low-fertility sites. Whole-plant carbon gain may be greater in shade-tolerant species due to higher total leaf area, despite lower leaf-level carbon assimilation rates. Alternatively, rates of carbon loss may be higher in more light-demanding species: higher rates of litterfall, respiration or allocation to roots, are all plausible mechanisms. However, the relationships between ρ and AGB and diameter increments were weak; resource availability always exerted a stronger influence on tree growth rates. [ABSTRACT FROM AUTHOR]

Published

2008

3. The global relationship between forest productivity and biomass.

Author

Keeling, Helen C. and Phillips, Oliver L.

Subjects

*FOREST productivity, *FOREST biomass, *CARBON, *CLIMATE change, *BIOTIC communities, *CARBON sequestration, *SOILS

Abstract

Aim We aim to determine the empirical relationship between above-ground forest productivity and biomass. There are theoretical reasons to assume a relationship between forest structure and function, as both may be influenced by similar ecological factors such as moisture supply. Also, dynamic global vegetation model simulations imply that any increase in forest productivity driven by climate change will result in increases in biomass and therefore carbon storage. However, few studies have explored the strength and form of the relationship between forest productivity and biomass, whether in space or time. Location Global scale. Methods We collated a large data set of above-ground biomass (AGB) and above-ground net primary productivity (ANPP) and tested the extent to which spatial variation in forest biomass across the Earth can be predicted from forest productivity. Results The global ANPP–AGB relationship differs fundamentally from the strongly positive, linear relationship reported in earlier analyses, which mostly lacked tropical sites. AGB begins to peak at c. 15–20 Mg ha−1 year−1 ANPP, plateaus at ANPP > 20–25 Mg ha−1 year−1, and may actually decline at higher levels of production. Main conclusions High turnover rates in high-productivity forests may limit AGB by promoting the dominance of species with a low wood density. Predicted increases in ANPP will not necessarily favour increases in forest carbon storage, especially if changes in productivity are accompanied by compositional shifts. [ABSTRACT FROM AUTHOR]

Published

2007