Nitrogen Balance and Loss in a Greenhouse Vegetable System in Southeastern China

Abstract High rates of fertilizer nitrogen (N) are applied in greenhouse vegetable fields in southeastern China to maximize production; however, the N budgets of such intensive vegetable production remain to be explored. The goal of this study was to determine the annual N balance and loss in a greenhouse vegetable system of annual rotation of tomato, cucumber, and celery at five N (urea) application rates (0, 348, 522, 696, and 870 kg N ha −1 year −1 ). Total N input to the 0–50 cm soil layer ranged from 531 to 1 053 kg ha −1 , and N fertilizer was the main N source, accounting for 66%–83% of the total annual N input. In comparison, irrigation water, wet deposition, and seeds in total accounted for less than 1% of the total N input. The fertilizer N use efficiency was only 18% under the conventional application rate of 870 kg N ha −1 and decreased as the application rate increased from 522 to 870 kg N ha −1 . Apparent N losses were 196–201 kg N ha −1 , of which 71%–86% was lost by leaching at the application rates of 522–870 kg N ha −1 . Thus, leaching was the primary N loss pathway at high N application rates and the amount of N leached was proportional to the N applied during the cucumber season. Moreover, dissolved organic N accounted for 10% of the leached N, whereas NH 3 volatilization only contributed 0.1%–0.6% of the apparent N losses under the five N application rates in this greenhouse vegetable system.

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