The interactions of climate, spacing and genetics on clonal Eucalyptus plantations across Brazil and Uruguay

•Survival and growth of Eucalyptus are examined across a 3500km gradient.•Stemwood production increased by 0.4–1.5Mgha−1yr−1 for each 100mmyr−1 increase in precipitation.•Stemwood production declined by by 2.5Mgha−1yr−1 for each 1°C temperature increase.•Production varied strongly among genotypes, w...

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Published in:Forest ecology and management 2017-12, Vol.405, p.271-283
Main Authors: Binkley, Dan, Campoe, Otávio C., Alvares, Clayton, Carneiro, Rafaela L., Cegatta, Ítalo, Stape, Jose Luiz
Format: Article
Language:English
Subjects:
Forest Science
Skogsvetenskap
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Summary:•Survival and growth of Eucalyptus are examined across a 3500km gradient.•Stemwood production increased by 0.4–1.5Mgha−1yr−1 for each 100mmyr−1 increase in precipitation.•Stemwood production declined by by 2.5Mgha−1yr−1 for each 1°C temperature increase.•Production varied strongly among genotypes, with the best clones growing 1.5–4Mgha−1yr−1 more than the average for all clones within a site. Intensively managed plantations account for 1.5% of the world’s forests, but they meet one-third of the demand for wood products. Eucalyptus plantations are among the most productive, with rates of growth depending heavily on genetics, silviculture, and climate. The TECHS Project examines productivity at 36 locations across a 3500km gradient from Brazil to Uruguay, testing the interacting influences of genetics, temperature and precipitation on stemwood production. Across all sites and genotypes, stemwood production in the middle of the 6-year rotation (the peak period of growth) averaged 22Mgha−1yr−1. Production varied by fivefold across sites, and by about 2-fold among genotypes within each site. The best clones at each location grew 1.5–4Mgha−1yr−1 more than the average for all clones, underscoring the importance of matching genotypes to local site conditions. Contrary to patterns for natural forests across geographic gradients, Eucalyptus production declined with increasing temperature, dropping by 2.5Mgha−1yr−1 for a 1°C temperature increase. The temperature effect was likely driven in part by the geographic covariance of temperature and rainfall, as rainfall tended to decline by 78mmyr−1 for each 1°C increase in temperature. Stemwood production increased an average of 1.5Mgha−1yr−1 for each 100mmyr−1 increase in precipitation, but when the covariation of temperature and precipitation were included the apparent influence of precipitation declined to 0.4Mgha−1yr−1 for each 100mmyr−1 increase in precipitation. Future results will determine if within-site reductions in ambient rainfall have the same apparent influences as the rainfall pattern across the geographic gradient, as well as quantifying the importance of insects and pests in affecting growth. The supply of wood from intensively managed plantations will be strongly influenced by both temperature and precipitation at plantation locations, and with changing climates.
ISSN:0378-1127
1872-7042
1872-7042
DOI:10.1016/j.foreco.2017.09.050