Effects of elevated CO2 concentration on leaf characteristics and photosynthetic capacity of beech (Fagus sylvatica) during the growing season

Abstract

Two-year-old beech (Fagus sylvatica L.) saplings were planted directly in the ground at high density (100 per m²), in an experimental design that realistically mimicked field conditions, and grown for two years in air containing CO₂ at either ambient or an elevated (ambient + 350 ppm) concentration. Plant dry mass and leaf area were increased by a two-year exposure to elevated CO₂. The saplings produced physiologically distinct types of sun leaves associated with the first and second growth flushes. Leaves of the second flush had a higher leaf mass per unit area and less chlorophyll per unit area, per unit dry mass and per unit nitrogen than leaves of the first flush. Chlorophyll content expressed per unit nitrogen decreased over time in plants grown in elevated CO₂, which suggests that, in elevated CO₂, less nitrogen was invested in machinery of the photosynthetic light reactions. In early summer, the photosynthetic capacity measured at saturating irradiance and CO₂ was slightly but not significantly higher in saplings grown in elevated CO₂ than in saplings grown in ambient CO₂. However, a decrease in photosynthetic capacity was observed after July in leaves of saplings grown in CO₂-enriched air. The results demonstrate that photosynthetic acclimation to elevated CO₂ can occur in field-grown saplings in late summer, at the time of growth cessation.