Growth and Yield of Tomato Plants as Influenced by Nutrient Application Rates with Quantitative Control in Closed Rockwool Cultivation

Abstract

We compared the effects of quantitative control in closed system versus electrical conductivity (EC)-based control in open system of nutrients on the growth and yield of tomatoes in rockwool cultivation. Quantitative control supplied all nutrients once a day based on criteria for three application rates (1.0 ×, 1.25 ×, and 1.5 × the standard). These criteria were previously developed in the deep flow technique (DFT) to estimate their nutrient requirements, which used the three-day average amount of water absorbed by tomato plants. We compared the quantitative control in a closed system with two EC treatments in an open system, in which we supplied nutrient solution at high and low EC ranges. The 1.0 × quantity standard reduced the nutrient supply to 30–37% of the levels used in the low-EC treatment. N, P, and K concentrations in the 1.0 × substrate solution remained low and stable for two months after transplanting. The 1.0 × treatment had 27% lower total leaf dry weight and 23% higher total fruit yield than the low-EC treatment. However, greatly reduced growth and nitrogen content of upper leaf and slightly lower soluble solids content in the fruits suggest that the 1.0 × standard might provide insufficient nutrients during late growth stages. Excessive nutrient supplies, which were much lower than the low-EC treatment, increased substrate salinity owing to the accumulation of nutrients during the latter half of the growth period in the 1.25 × and 1.5 × treatments. The stable EC and nutrient concentrations in the 1.0 × substrate solution over time suggest that the three-day adjustment interval would be short enough. The quantity criteria developed for the DFT system could generally be applied to long-term rockwool culture, but the optimum range of nutrient supply was found to be from 1.0 × to 1.25 × the DFT standard in the later growth stages.