Interactions between drought and elevated CO2 on growth and gas exchange of seedlings of three deciduous tree species

Abstract

Interactions between elevated atmospheric CO₂ and drought on growth and gas exchange of American sycamore (Platanus occidentalis L.), sweetgum (Liquidambar styraciflua L.) and sugar maple (Acer saccharum Marsh.) were investigated using 1‐yr‐old seedlings, planted in 8 1 pots and grown in four open‐top chambers, containing either ambient air or ambient air enriched with 300 μmol mol⁻¹CO₂. Two soil moisture regimes were included within each chamber: a ‘well‐watered’ treatment with plants watered daily and a ‘drought’ treatment in which plants were subjected to a series of drought cycles. Duration and depth of the drought cycles were determined by soil matric potential. Mean soil water potential at rewatering for the water‐stressed seedlings under ambient CO₂ for sugar maple, sweetgum and sycamore was −0.5, −0.7 and −1.8 MPa, respectively, compared with > −0.1 MPa for all well–watered plants. Elevated CO₂ increased relative growth rate of well‐watered sugar maple by 181%, resulting in a 4.3‐fold increase in total plant dry weight after 81 d, compared with 1.4 and 1.6‐fold increases for sweetgum and sycamore, respectively, after 69 d. Although elevated CO₂ increased net CO₂ assimilation rate of sugar maple by 115%, there was a 10‐fold increase in leaf area which contributed to the growth response. Although drought did not eliminate a growth response of sugar maple to elevated CO₂ it greatly reduced the elevated CO₂‐induced enhancement of relative growth rate. In contrast, relative growth rates of sweetgum and sycamore were not significantly increased by elevated CO₂. Drought, under elevated CO₂, reduced leaf area of all three species to a greater extent than it reduced net CO₂ assimilation rate. The response ranged from no effect in sugar maple to a 40 % reduction in sycamore, with sweetgum exhibiting an intermediate response. Results indicate that drought may alter the growth response, gas exchange and water relations of tree species growing in an elevated CO₂ atmosphere. Under high nutrient and water availability, sugar maple may benefit the most (of the three species studied) from a CO₂‐ enriched atmosphere, but productivity gains will be limited if frequent drought is prevalent.