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我国北方立体种养殖稻田氮素利用率研究
引用本文:杨亚男,张晓惠,陈 红,焦永杰,邓小文,袁雪竹,董 菁,杨 静. 我国北方立体种养殖稻田氮素利用率研究[J]. 中国生态农业学报, 2015, 23(7): 812-822
作者姓名:杨亚男  张晓惠  陈 红  焦永杰  邓小文  袁雪竹  董 菁  杨 静
作者单位:天津工业大学环境与化学工程学院 天津 300387,天津市环境保护科学研究院 天津 300191,天津市环境保护科学研究院 天津 300191,天津市环境保护科学研究院 天津 300191,天津市环境保护科学研究院 天津 300191,天津市环境保护科学研究院 天津 300191,天津市环境保护科学研究院 天津 300191,天津市环境保护科学研究院 天津 300191
基金项目:国家重大科技专项课题(2012ZX07203)资助
摘    要:针对目前我国北方地区农业面源污染严重、氮肥利用率低的现象,选择北方典型稻区——天津市宝坻水稻种植区为研究区,以整个稻田生态系统为基本研究单元,建立氮素输入和输出模型,并以水稻普通种植模式(CK,水稻单作)为对照进行田间试验,研究水稻立体种养殖模式(RF,水稻-鱼-虾-蟹共作+田埂+沟渠)氮素的吸收利用率。结果表明,两种水稻种植模式氮素的输入主要来自灌溉、施肥和降雨,其中RF输入氮肥128.25 kg(N)·hm-2,与CK相比减少11.75 kg(N)·hm-2,与南方种植水稻地区相比,氮肥施用量减少14%~52%,RF从源头减少氮素输入,降低了营养元素流失风险。CK氮素的输出主要包括土壤固定、氨挥发、侧渗流失和水稻吸收,RF与CK相比,氮素的输出还包括鱼虾蟹的吸收,由于RF特殊的田埂-沟渠生态净化系统,通过侧渗损失的氮素(以NO3--N为主)较CK减少9.33 kg(N)·hm-2。试验期间,RF和CK氨累积挥发量分别为8.91kg(N)·hm-2和21.54 kg(N)·hm-2,RF氨挥发速率为6.9%,比CK低8.5%,比全国平均水平低10.3%;收获期,RF与CK相比,水稻产量增加6.65%,表明稻田养殖鱼虾蟹不会降低水稻产量。RF氮素利用率为64.3%,比CK高19.7%,既实现了水稻丰产,又减少了氮素流失。因此,在满足水稻灌溉需求的北方地区,可以开展水稻立体种养殖模式,以控制北方地区农业面源污染。

关 键 词:北方稻区 立体种养殖 氮输入/输出 氨挥发 侧渗 氮素利用效率
收稿时间:2015-01-23
修稿时间:2015-05-05

Nitrogen use efficiency in stereoscopic planting rice field in North China
YANG Yanan,ZHANG Xiaohui,CHEN Hong,JIAO Yongjie,DENG Xiaowen,YUAN Xuezhu,DONG Jing and YANG Jing. Nitrogen use efficiency in stereoscopic planting rice field in North China[J]. Chinese Journal of Eco-Agriculture, 2015, 23(7): 812-822
Authors:YANG Yanan  ZHANG Xiaohui  CHEN Hong  JIAO Yongjie  DENG Xiaowen  YUAN Xuezhu  DONG Jing  YANG Jing
Affiliation:School of Environment and Chemical Engineering, Tianjin Polytechnic University, Tianjin 300387, China,Tianjin Academy of Environmental Sciences, Tianjin 300191, China,Tianjin Academy of Environmental Sciences, Tianjin 300191, China,Tianjin Academy of Environmental Sciences, Tianjin 300191, China,Tianjin Academy of Environmental Sciences, Tianjin 300191, China,Tianjin Academy of Environmental Sciences, Tianjin 300191, China,Tianjin Academy of Environmental Sciences, Tianjin 300191, China and Tianjin Academy of Environmental Sciences, Tianjin 300191, China
Abstract:To control serious agricultural non-point source pollution and improve use efficiency of nitrogen (N) fertilizer in North China, this study investigated nitrogen use efficiency in different planting patterns of paddy fields in a typical rice cultivation zone in Baodi of Tianjin City. With an entire paddy field ecosystem as the basic research unit, N migration and transformation model in paddy field was established based on N input and output. In order to explore N uptake and use efficiency in coTo control serious agricultural non-point source pollution and improve use efficiency of nitrogen (N) fertilizer in North China, this study investigated nitrogen use efficiency in different planting patterns of paddy fields in a typical rice cultivation zone in Baodi of Tianjin City. With an entire paddy field ecosystem as the basic research unit, N migration and transformation model in paddy field was established based on N input and output. In order to explore N uptake and use efficiency in conventional rice field pattern (CK: rice monoculture) and stereoscopic planting rice field pattern (RF: rice-fish-shrimp-crab co-culture + bund + ditch), a field experiment was conducted to analyze the characteristics of N input and N output. The differences in N use efficiency and yield of rice between two paddy planting patterns were investigated too. Results showed that N input of two rice field patterns was mainly from irrigation, fertilization and precipitation. N input from fertilizer in RF system was 128.25 kg(N)·hm-2, 11.75 kg(N)·hm-2 less than that of CK, and was 14%52% less than that of other rice planting regions in South China. In RF system, N input at source was limited, thus reducing the risk of nutrient loss. N output of CK system was composed of soil fixation, ammonia volatilization, N loss via lateral seepage, and crop N uptake. In addition to components of N output of CK, N output of RF system contained N absorptions by fishes, shrimps and crabs. Due to special bund-ditch ecological purification in RF system, N loss through lateral seepage dropped by 9.33 kg(N)·hm-2 and NO3-N was the main form of lateral seepage. N loss via ammonia volatilization in RF and CK systems was 8.91 kg·hm-2 and 21.54 kg·hm-2, respectively. Ammonia volatilization rate in RF system accounted for 6.9% of total amount of applied fertilizer, which was 8.5% less than that in CK and 10.3% less than the national average. Compared with CK, RF system harvested 6.65% higher rice yield. N uptake by rice and aquatic materials was 271.72 kg(N)·hm-2 in RF system, 255.05 kg(N)·hm-2 in CK system. The results suggested that breeding fishes, shrimps and crabs did not reduced rice yield. N use efficiency in RF system reached 64.3%, which was 19.7% higher than that in CK. RF not only achieved high rice yield, but also reduced N loss in paddy fields. Therefore stereoscopic planting rice field was feasible in North China where irrigation demands were well met. This study provided a critical reference for controlling agricultural non-point source pollution in North China.
Keywords:Rice region in North China   Stereoscopic planting paddy field   Nitrogen input/output   Ammonia volatilization   Lateral seepage   Nitrogen use efficiency
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