Annals of Botany

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Annals of Botany 80: 809-816, 1997
© 1997 Annals of Botany Company

Growth Response of Young Birch Trees (Betula pendulaRoth.) After Four and a Half Years of CO₂Exposure

ANA REY^+, and PAUL G. JARVIS

IERM, Darwin Building, Edinburgh University, Mayfield Road, Edinburgh, EH9 3JU, U.K.

May 12, 1997 ; July 7, 1997 . September 3, 1997 .

A field experiment consisting of 18 birch trees grown in open top chambers in ambient and elevated CO₂concentrations was set up with the aim of testing whether the positive growth response observed in many short-term studies is maintained after several growing seasons. We present the results of growth and biomass after 4.5 years of CO₂exposure, one of the longest studies so far on deciduous tree species. We found that elevated CO₂led to a 58% increase in biomass at the end of the experiment. However, estimation of stem mass during the growing season showed that elevated CO₂did not affect relative growth rate during the fourth growing season, and therefore, that the large accumulation of biomass was the result of an early effect on relative growth rate in previous years. Trees grown in elevated CO₂invested more carbon into fine roots and had relatively less leaf area than trees grown in ambient CO₂. In contrast with previous studies, acceleration of growth did not involve a significant decline in nutrient concentrations of any plant tissue. It is likely that increased fine root density assisted the trees in meeting their nutrient demands. Changes in the species composition of the ectomycorrhizal fungi associated with the trees grown in elevated CO₂in favour of late successional species supports the hypothesis of an acceleration of the ontogeny of the trees in elevated CO₂.Copyright 1997 Annals of Botany Company

Betula pendula; silver birch; elevated CO₂; growth; biomass allocation; ectomycorrhizas; tissue composition; nutrients; leaf morphology; specific leaf area; stomatal density; shoot structure

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