Eucalyptus production and the supply, use and efficiency of use of water, light and nitrogen across a geographic gradient in Brazil

Millions of hectares of Eucalyptus are intensively managed for wood production in the tropics, but little is known about the physiological processes that control growth and their regulation. We examined the main environmental factors controlling growth and resource use across a geographic gradient with clonal E. grandis × urophylla in north-eastern Brazil. Rates of production and resource use were estimated for 14 stands that spanned a four-fold range in production. Above-ground net primary production (ANPP) increased by 2.3 Mg ha−1 per year for each 100 mm per year increase in rainfall. Higher water supply was also associated with increased use of light and nitrogen (N). The efficiency of resource use increased with increasing productivity along the gradient. The most efficient stands produced 3.21 kg ANPP m−3 of transpired water, 1.14 kg ANPP GJ−1 absorbed photosynthetically active radiation (PAR), and 381 kg ANPP kg−1 N taken up. The stands with high resource use and high efficiency also had lower mean vapor pressure deficits, less soil water stress, and smaller coarse root to above-ground biomass ratios. Our study indicates that the productivity of fertilized tropical plantations of Eucalyptus is most likely constrained by water supply, and that water supply substantially affects the efficiency of resource use as well as biomass allocation to roots, stems, and leaves. At a regional scale, our results indicate that high productivity stands could produce wood in a 6-year rotation on half the land area required for low productivity stands, using only half as much water.

Saved in:
Bibliographic Details
Main Authors: 121471 Stape, Jose L University of Sao Paulo, SP (Brazil), 49024 Binkley, Dan (autor/a) Colorado State University, Fort Collins (Estados Unidos), 114348 Ryan, Michael G. (autor/a) USDA Forest Service, Fort Collins (Estados Unidos)
Format: Texto biblioteca
Language:eng
Published: Amsterdam Elsevier 2004
Subjects:EUCALYPTUS, PLANTACION FORESTAL, FISIOLOGIA VEGETAL, PROPIEDADES BIOLOGICAS, CONDICION DE LA PLANTA, CRECIMIENTO, ORDENACION DE RECURSOS, RELACIONES PLANTA AGUA, SECUESTRO DE CARBONO, PRODUCTIVIDAD, ALOMETRIA, BIOMASA, ECUACIONES ALOMETRICAS, FOREST PLANTATIONS, Plant physiology, BIOLOGICAL PROPERTIES, PLANT CONDITION, GROWTH, NATURAL RESOURCES MANAGEMENT, PLANT WATER RELATIONS, PRODUCTIVITY, BIOMASS,
Online Access:https://www.sciencedirect.com/science/article/abs/pii/S0378112704000477
Tags: Add Tag
No Tags, Be the first to tag this record!
Description
Summary:Millions of hectares of Eucalyptus are intensively managed for wood production in the tropics, but little is known about the physiological processes that control growth and their regulation. We examined the main environmental factors controlling growth and resource use across a geographic gradient with clonal E. grandis × urophylla in north-eastern Brazil. Rates of production and resource use were estimated for 14 stands that spanned a four-fold range in production. Above-ground net primary production (ANPP) increased by 2.3 Mg ha−1 per year for each 100 mm per year increase in rainfall. Higher water supply was also associated with increased use of light and nitrogen (N). The efficiency of resource use increased with increasing productivity along the gradient. The most efficient stands produced 3.21 kg ANPP m−3 of transpired water, 1.14 kg ANPP GJ−1 absorbed photosynthetically active radiation (PAR), and 381 kg ANPP kg−1 N taken up. The stands with high resource use and high efficiency also had lower mean vapor pressure deficits, less soil water stress, and smaller coarse root to above-ground biomass ratios. Our study indicates that the productivity of fertilized tropical plantations of Eucalyptus is most likely constrained by water supply, and that water supply substantially affects the efficiency of resource use as well as biomass allocation to roots, stems, and leaves. At a regional scale, our results indicate that high productivity stands could produce wood in a 6-year rotation on half the land area required for low productivity stands, using only half as much water.