摘要
通过田间微区试验,应用^(15)N标记技术研究两个施氮水平下硝化抑制剂CP施用对水稻产量、氮素利用率、氮素土壤残留和氨挥发的影响。结果表明:与推荐施氮处理(240 kg/hm^2)相比,减氮处理(180 kg/hm^2)水稻产量明显降低,但是减氮处理下施用硝化抑制剂CP后增产15.2%,差异显著,并且达到了推荐施氮处理下的产量水平。而推荐施氮处理下施用硝化抑制剂对水稻产量反而没有显著影响。施用硝化抑制剂可显著提高11.1%~25.0%的^(15)N吸收与利用效率,同时^(15)N平衡计算结果表明稻田施用硝化抑制剂减少了21.7%~28.1%的硝化?反硝化、径流等途径^(15)N损失,这可能是CP施用增加水稻产量的机理之一。然而,施用硝化抑制剂会增加54.7%~110.6%的氨挥发排放。因此,在水稻生产过程中施用硝化抑制剂CP时要进一步减施氮肥才有明显的增产效果,同时还需要采取一定的措施来控制氨挥发。
A micro-plot scale field experiment with two labeled 15N-urea input level, i.e., 180 kg/hm2 and 240 kg/hm2, was carried out to study the effects of nitrification inhibitor (2-Chloro-6-(trichloromethyl)-pyridine, CP) application on rice grain yield, N use efficiency, soil residual N and NH3 volatilization in a paddy rice field. The results showed that rice production of N180 was significantly lower than N240. For the plots of 180 kg/hm2 urea N, CP application increased the grain yield by 15.2% that reached to rice production in plots of 240 kg/hm2. However, CP had no impact on rice yield when N input level was 240 kg/hm2. CP application significantly promoted 15N use efficiency by 11.1%-25.0%. And the 15N balance results suggested that CP usage reduced 15N losses by 21.7%-28.1% via nitrification-denitrification and runoff. These probably were the mechanisms of rice yield increase. However, CP amendment increased NH3 losses by 54.7%-110.6%. These results indicate that CP application can maintain a high rice production at a sub-optimal N input level and meanwhile measures should be adopted to control higher NH3 volatilization in paddy soil applied with CP.
出处
《土壤》
CAS
CSCD
北大核心
2015年第6期1027-1033,共7页
Soils
基金
国家青年科学基金项目(31201686
41401345)
土壤与农业可持续发展国家重点实验室开放基金项目(Y412201425)
江苏省农业科技自主创新资金项目(CX(14)2050)的资助
关键词
硝化抑制剂
水稻
氨挥发
氮肥
Nitrification inhibitor
Rice
Ammonia volatilization
Nitrogen fertilizer
