Rapid and semi-automated leaf net photosynthetic rate determination for numerous phosphor-converted white-LED lights of different spectral distributions

Phosphor-converted white LEDs (PCW-LEDs) of numerous types with different relative spectral photon-flux-density distributions (SPDs) are commercially available today. Some are regarded as promising light sources for use in plant factories with artificial lighting. The leaf net photosynthetic rate (P-n) measured under PCW-LED light is an important criterion for evaluating PCW-LEDs in terms of photosynthesis performance. To ascertain P-n rapidly under dozens of PCW-LED lights having different SPDs, we have developed a rapid and semi-automated P-n-quantification method. The method uses a modified LED-artificial sunlight source system (LASS system) and a P-n-measurement system. The modified LASS system can produce light with an SPD, which can accurately approximate that of any PCW-LED light at a photosynthetic photon flux density (PPFD) of 150 mu mol m(-2) s(-1). First, PCW-LED lights of 30 types at a PPFD of 150 mu mol m(-2) s(-1) were produced using the modified LASS system within 2.5 h. We then measured the Pn of cos lettuce, red-leaf lettuce, and green-leaf lettuce (Lactuca sativa L.) plants. In a 16-h P-n measurement repetition, the modified LASS system supplied all the produced lights automatically and successively to an identical leaf of a lettuce plant. A P-n-measurement system simultaneously measured Pn under the produced light. Results show that the mean P-n values of the cos lettuce, red-leaf lettuce, and green-leaf lettuce under the 30 produced lights at 20 days after sowing were, respectively, 7.11-8.02, 5.76-7.11, and 4.83-6.17 mu mol m(-2) s(-1). A rapid and semi-automated method was developed for successive measurement of Pn under dozens of combined lights, of which each SPD approximated that of the selected PCW-LED lights, within days, which indicates that the method can determine the P-n quickly under numerous PCW-LED lights. Results show that the system contributes to rapid selection of PCW-LED lights performing high P-n.