Analysis and modeling of gas exchange processes in Scaevola aemula

Abstract

Scaevola aemula is a popular ornamental crop cultivated as a bedding plant or for hanging baskets. We characterized gas exchange properties of S. aemula ‘New Wonder’ in response to photosynthetically active radiation (PAR), carbon dioxide concentration, and leaf temperature. Net CO 2 assimilation rate ( A) was responsive to CO 2, exhibiting a saturation when intercellular CO 2 concentration ( C i) was greater than 600 μmol mol −1. Net CO 2 assimilation rate and dark respiration rate ( R d) were 23.1 and 2.3 μmol m −2 s −1, respectively, at 25 °C and PAR = 1500 μmol m −2 s −1. Net CO 2 assimilation rates were similar at leaf temperatures between 20 and 30 °C but significantly reduced at 15 °C. These gas exchange results were used to test the extendibility of a coupled gas exchange model previously developed for cut-roses. Utilizing the gas exchange data measured at 25 °C leaf temperature, several model parameters were independently determined for S. aemula. Model predictions were then compared with observations at different leaf temperatures. The model predicted the rates of net CO 2 assimilation and transpiration of S. aemula reasonably well. Without additional calibration, the model was capable of predicting the temperature dependence of net CO 2 assimilation and transpiration rates. Applying the model to predict the effects of supplemental lighting and CO 2 enrichment on canopy photosynthesis and transpiration rates, we show that this model could be a useful tool for examining environmental control options for S. aemula production in the greenhouse.