模拟施用于近沟渠稻田的尿素中氮的迁移与归宿。

Modeling transport and fate of nitrogen from urea applied to a near-trench paddy field.

作者信息

Liang X Q, Chen Y X, Li H, Tian G M, Ni W Z, He M M, Zhang Z J

机构信息

Department of Environmental Engineering, College of Natural Resources and Environmental Science, Zhejiang University, Hangzhou, 310029, China.

出版信息

Environ Pollut. 2007 Dec;150(3):313-20. doi: 10.1016/j.envpol.2007.02.003. Epub 2007 Mar 19.

DOI:10.1016/j.envpol.2007.02.003

PMID:17374427

Abstract

A simple but comprehensive model is developed to quantify N losses from urea applied to a near-trench paddy field, considering all the N-transformations such as urea hydrolysis, volatilization, nitrification, denitrification, and all the important transportations like runoff, lateral seepage, vertical leaching and crop uptake. Seasonal average data of field observations for three crop seasons were used for model calibration and validation, which showed that ammonia volatilization accounted for 26.5-29.4% of the applied N and N uptake by crop occupied 38.2-44.8%, while N losses via surface runoff, vertical leaching and lateral seepage varied from 5.6-7.7%, 4.0-4.9% to 5.0-5.3% of the applied N, respectively. These observed results were well predicted by our model, indicating that the model performed effectively at quantifying N losses via individual processes in a wide range of urea application rates and benefit for developing water and fertilizer management strategies for near-trench paddy fields.

摘要

开发了一个简单但全面的模型，用于量化施用于近沟稻田的尿素的氮损失，该模型考虑了所有氮转化过程，如尿素水解、挥发、硝化、反硝化，以及所有重要的迁移过程，如径流、侧向渗漏、垂直淋溶和作物吸收。利用三个作物季的田间观测季节性平均数据对模型进行校准和验证，结果表明，氨挥发占施氮量的26.5-29.4%，作物吸氮占38.2-44.8%，而通过地表径流、垂直淋溶和侧向渗漏造成的氮损失分别占施氮量的5.6-7.7%、4.0-4.9%和%5.0-5.3%。我们的模型对这些观测结果进行了很好的预测，表明该模型在量化不同尿素施用量下各个过程的氮损失方面表现有效，有助于制定近沟稻田的水肥管理策略。

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模拟施用于近沟渠稻田的尿素中氮的迁移与归宿。

Modeling transport and fate of nitrogen from urea applied to a near-trench paddy field.

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