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Incorporation of urea for transplanted rice as affected by floodwater and growing season

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Abstract

Incorporation of urea into puddled rice soils is known to reduce ammoniacal-N buildup in floodwater and the subsequent loss of N as ammonia. Little is known, however, about seasonal and temperature effects on the effectiveness of basal urea incorporation in puddled soils. A field experiment was conducted in northern Vietnam on an Aquic Ustifluvent in the spring season (February to June) and summer season (July to November) to determine the effect of the presence of floodwater and method of fertilizer incorporation on floodwater ammoniacal-N, floodwater urea-N, andpNH3 following urea application. During the 4 d following basal urea application, floodwater temperature at 1400 h was 7 to 15°C higher in summer (July) than that in spring (February), and floodwater pH at 1400 h was 0.5 to 1.0 higher in summer than that in spring. ThepNH3 was much higher in summer than that in spring, suggesting a high potential for ammonia volatilization in summer. The movement of transplanters through the field did not reducepNH3, irrespective of floodwater depth (0 or 5 cm) and season. Harrowing and subsequent transplanter movement partially reducedpNH3 in the summer;pNH3 reduction, however, was greater when floodwater depth was 0 rather than 5 cm during harrowing and transplanting. This partial reduction ofpNH3 in summer did not result in a corresponding increase in rice yield, presumably because N losses were only slightly reduced and because yield was constrained by additional factors, such as the adverse climate. In spring, the removal of floodwater before urea application and incorporation increased grain yield by 0.2 Mg ha−1, even thoughpNH3 was consistently low and was not reduced by urea incorporation. This result suggests that water management and tillage during basal urea application may influence rice growth and yield in ways other than reduced N loss.

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Author notes

  1. R. J. Buresh

    Present address: International Centre for Research in Agroforestry (ICRAF), P.O. Box 30677, Nairobi, Kenya

Authors and Affiliations

  1. Institute for Soils and Fertilizers, Hanoi, Vietnam

    Tran Thuc Son

  2. International Fertilizer Development Center, Muscle Shoals, P.O. Box 2040, 35662, AL, USA

    R. J. Buresh

  3. International Rice Research Institute, P.O. Box 933, Manila, Philippines

    R. J. Buresh

Authors
  1. Tran Thuc Son
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  2. R. J. Buresh
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Son, T.T., Buresh, R.J. Incorporation of urea for transplanted rice as affected by floodwater and growing season. Fertilizer Research 34, 111–120 (1993). https://doi.org/10.1007/BF00750105

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  • DOI: https://doi.org/10.1007/BF00750105

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