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Interaction of Atmospheric CO₂ Enrichment and Irradiance on Plant Growth¹

Atmospheric carbon dioxide and irradiance are important factors affecting growth and yield of plants. Due to the wide variation in irradiance in natural plant stands and the reportedly increasing carbon dioxide concentration in the global atmosphere, it is essential to study the interacting effects of these factors on the growth and production of crop plants. Growth analysis techniques were used to study the interaction of atmospheric CO₂ concentration (350 and 675 µl/l) and photosynthetic photon flux density (PPFD) (600 and 1200 µEM^–2 s–¹)on four species (including both seed and root crops) grown in controlled environment chambers of the Duke University Phytotron. The plants were soybean (Glycine max L. Merr.), radish (Raphanus sativus L.), sugarbeet (Beta vulgaris L.), and corn (Zea mays L.). Total dry matter production increased in all species of plants and at all growth stages with both increased CO₂ concentration and PPFD levels, and the maximum dry matter was produced at the highest combined levels of CO₂ and PPFD. The dry weight increase varied between the different species and between plant parts within a species. High levels of CO₂ and PPFD caused a greater increase in net assimilation rate in the plants during early growth stages than in later stages because the first two or three young, rapidly growing leaves were very efficient photosynthetic organs. A high CO₂ or PPFD level resulted in decreasing leaf area ratios with increasing plant age for all the species due to a rapid increase in stem and root growth later in fruit production, and to a decreasing specific leaf area.

Corn, having the C₄ pathway of photosynthesis, showed less response to increased CO₂ and PPFD than the three C₃ species. Increasing the atmospheric CO₂ concentration from 350 to 675 µl/liter at low and high PPFD levels produced dry matter increases of 72.7 and 76.4%, respectively, in soybean, and 18.9 and 18.6%, respectively, in corn at 50 days after planting. None of the species tested were light saturated at levels available in the standard fluorescent and incandescent lighting as is shown by the increased growth when higher PPFD levels were obtained with a combination of multivapor and sodium lamps.

Key Words: Growth analysis • Biomass partitioning • Phostosynthetic photon flux density

² Senior research scientist and professors of Botany, Botany Dep., Duke Univ., Durham, N.C., respectively.

Received for publication October 22, 1981.

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