尿素施肥方式对水稻增产增效和土壤氮素损失的影响

【目的】探讨尿素施用量、基施比例和方法对水稻产量、吸氮量和氮肥利用率的影响,以及肥料氮的去向,为制定科学合理的施氮措施提供理论依据。【方法】水稻季田间试验于2019年和2020年在江苏太湖地区开展。供试脲酶抑制剂为N-丁基硫代磷酰三胺(NBPT),硝化抑制剂为对羟基苯丙酸甲酯(MHPP),二者用量均为施氮量的1%。试验共设6个处理:1)不施氮肥对照(CK);2)表施尿素N 300 kg/hm^(2)(当地常规施肥,CN);3)表施尿素N 225 kg/hm^(2)(RNB);4)尿素N 225 kg/hm^(2),50%表施,50%深施(RND);5)表施尿素N 225 kg/hm^(2)+NBPT+MHPP(RNB+DI);6)尿素N 225 kg/hm^(2)+NBPT+MHPP,50%表施,50%深施(RND+DI)。表施氮肥处理基肥∶分蘖肥∶孕穗肥为4∶3∶3;深施氮肥处理基肥∶孕穗肥为7∶3。2020年在处理小区内设置了^(15)N示踪微区试验。调查了水稻产量、吸氮量、氮肥利用率以及^(15)N肥料植株利用、土壤残留和总损失量。【结果】与CN相比,除RNB处理2020年的秸秆生物量外,其余三个处理的籽粒与秸秆生物量均无显著差异;两年4个处理的氮肥表观利用率、农学利用率和偏生产力利用率均显著提高;15N示踪试验结果表明,4个处理均显著减少了^(15)N吸收量,RND、RNB+DI和RND+DI还显著降低了氮肥总损失量。与RNB相比,RND处理的水稻产量增加3.3%—4.0%,氮肥表观利用率显著增加20.4%—27.3%,^(15)N吸收量和利用率显著增加28.2%,总损失率显著降低34.6%;RNB+DI处理的水稻产量和氮肥表观利用率没有显著增加,15N吸收量和利用率显著增加11.6%,总损失率显著降低13.1%;RND+DI处理的水稻产量增加2.6%—4.3%,氮肥表观利用率显著增加23.4%,^(15)N吸收量和利用率显著增加36.9%,损失率显著降低45.0%。与RND相比,RND+DI处理的水稻产量、氮肥利用率和^(15)N植株吸收量均无显著差异,但降低了总损失率。【结论】在太湖地区水稻生产中,将氮肥用量由N 300 kg/hm^(2)减至225 kg/hm^(2),基施比例由40%提高到70%,同时将基肥中的50%深施,不会降低水稻产量,还显著提高了氮肥利用率,降低了氮肥总损失率,将此技术与添加氮肥抑制剂技术集成,可进一步降低氮素的损失率。从生产成本和应用效果考虑,减少氮肥总量的前提下,加大氮肥基施比例并配合基肥深施加少量撒施,是提高水稻产量和效益的适宜措施。

施氮方式与添加脲酶/硝化抑制剂对稻季NH_(3)挥发和N_(2)O排放的影响

【目的】分析施肥方式及添加脲酶/硝化抑制剂对稻田NH3挥发和N_(2)O排放的影响,基于稻田NH_(3)和N_(2)O减排的效果评价优化施肥措施的可行性。【方法】在太湖地区开展为期两年的稻季田间小区试验,供试脲酶抑制剂为N-丁基硫代磷酰三胺(NBPT),硝化抑制剂为对羟基苯丙酸甲酯(MHPP),用量为施氮量的1%。设置6个处理:1)不施氮肥对照(CK);2)表施尿素N 300 kg/hm^(2)(当地常规施肥,CN);3)表施尿素N 225 kg/hm2(RNB);4)尿素N 225 kg/hm^(2),50%表施,50%深施(RND);5)表施尿素N 225 kg/hm^(2)+NBPT+MHPP(RNB+DI);6)尿素N 225 kg/hm^(2)+NBPT+MHPP,50%表施,50%深施(RND+DI)。每次施肥后两周内,用密闭式抽气法监测稻田NH3挥发,在水稻生育期内用静态箱—气相色谱法监测稻田N2O排放。【结果】1) NH_(3)挥发主要发生在每次施氮后7天内,CN、RNB和RNB+DI处理基肥和分蘖肥施用后的NH3挥发量占总挥发量的86.63%~91.76%;稻季N_(2)O排放峰期主要出现在每次施肥后一周内和中期烤田期。2) RNB比CN处理可减少NH3挥发总量29.69%~39.41%和N_(2)O排放总量13.43%~23.37%。3) RND比RNB处理可减少NH_(3)挥发总量53.50%~72.05%和N2O排放总量16.66%~23.43%。4) RNB+DI比RNB处理可减少NH3挥发总量9.57%~22.27%和N_(2)O排放总量8.77%~15.67%。5) RND+DI比CN处理可减少NH3挥发总量76.89%~82.29%和N_(2)O排放总量37.98%~48.71%。【结论】尿素总氮投入减少25%,50%由撒施改为基肥深施,并添加脲酶/硝化抑制剂,可显著减少稻季NH3挥发和N2O总排放,特别是降低NH3挥发的效果更佳;将这3种措施组合集成的RND+DI处理减排效果最佳。该综合集成措施的实际操作性强,为在水稻生产上推广应用提供了技术支撑。

聚脲甲醛缓释肥对太湖稻麦轮作体系氨挥发及产量的影响

【目的】通过研究尿素和聚脲甲醛缓释肥(MU)对太湖地区稻麦轮作体系氨挥发、氮肥利用率及产量的影响,为新型缓释肥料的推广和降低农田氨挥发损失提供理论依据。【方法】田间小区试验在江苏苏州进行,种植制度为水稻小麦轮作,供试聚脲甲醛缓释氮肥有两个,MU70 (含氮量39%)和MU50 (含氮量40%),供试土壤为潜育型水稻土。除对照外,施氮量稻季为N 270 kg/hm^2,麦季为N 190 kg/hm^2。以施用普通尿素为对照,试验共设6个处理,分别为100%MU50 (单施缓释肥)、100%MU70、50%MU50 (缓释肥配施尿素)、50%MU70、当地常规(U)和对照(CK)。各处理中缓释肥全部用于基施,尿素分三次追施。施肥后的第二天采用密闭室间歇通气—稀硫酸吸收法测定田间氨挥发通量。收获期测产,计算各处理的经济收益。【结果】氨挥发主要发生在稻季,稻季施用MU可降低稻田的氨挥发损失,表现为100%MU50≈100%MU70 <50%MU50≈50%MU70 <U。相比U处理,单施MU可导致水稻减产,而MU配施尿素可保证产量,50%MU50和50%MU70的产量比U处理分别提高了5.7%和3.2%;麦季单施MU处理的氨挥发和产量均显著低于U处理,50%MU50和U处理的氨挥发和产量无明显差异,而50%MU70处理的氨挥发损失高于U处理。稻季和麦季的MU与尿素配施处理的氮肥利用率均高于U处理的,而单施MU处理的氮肥利用率均显著低于U处理的,其中不同的是,稻季50%MU50处理的氮肥利用率比U处理显著提高了8.1%;麦季50%MU70处理的氮肥利用率比U处理的显著提高3%。【结论】综合考虑农学和环境效益,稻麦轮作体系50%MU50的总净收入是30259元/hm^2,相比U处理(30168元/hm^2)差异不大,但前者显著降低了氨挥发损失,提高了氮肥利用率。因此,MU50和尿素1∶1配施模式值得在太湖地区推广应用。

Nitrogen Runoff and Leaching Losses During Rice-Wheat Rotations in Taihu Lake Region,China

Although nitrogen （N） loss through runoff and leaching from croplands is suspected to contribute to the deterioration of surrounding water systems, there is no conclusive evidence for paddy soils to prove this hypothesis. In this study, field plot experiments were conducted to investigate N losses through runoff and leaching for two consecutive years with 3 N fertilization rates in rice （Oryza sativa L.）-wheat （Triticum aestivum L.） rotations in the Taihu Lake region, China. A water collection system was designed to collect runoff and leachates for both the rice and wheat seasons. Results showed that dissolved N （DN）, rather than particulate N （PN）, was the main form of N loss by runoff. The NO3^--N concentration in runoff was between 0.1 and 43.7 mg L^-1, whereas the NH4^＋-N concentration ranged from below detection limit to 8.5 mg L^-1. Total N （TN） loads by runoff were 1.0-17.9 and 5.2-38.6 kg ha^-1 during rice and wheat seasons, respectively, and the main loss occurred at the early growing stage of the crops. Nitrogen concentrations in leachates during the rice seasons were below 1.0 mg L^-1 and independent of the N application rate, whereas those during the wheat season increased to 8.2 mg L^-1 and were affected by the fertilizer rate. Annual losses of TN through runoff and leaching were 13.7-48.1 kg ha^-1 from the rice-wheat cropping system, accounting for 5.6%-8.3% of the total applied N. It was concluded that reduction in the N fertilization rate, especially when the crop was small in biomass, could lower the N pollution potential for water systems.

碳纤维增强复合材料层间剪切强度测量不确定度的评定

依据JC/T 773-2010/IS0 14130:1997《纤维增强塑料短梁法测定层间剪切强度》,测定了CCF800H-12K碳纤维增强复合材料的层间剪切强度。根据测量不确定度评定与表示理论,分析得出复合板层间剪切强度测量过程中的测量不确定度来源主要为重复性测量、厚度和宽度的测量、电子万能试验机及测量结果的数据修约。推算得出当平均层间剪切强度为106.3MPa时,测量结果的扩展测量不确定度为3.0MPa。

Optimizing Nitrogen Fertilizer Application for Rice Production in the Taihu Lake Region,China

To determine the optimal amount of nitrogen(N) fertilizer for achieving a sustainable rice production at the Taihu Lake region of China,two-year on-farm field experiments were performed at four sites using various N application rates.The results showed that 22%-30% of the applied N was recovered in crop and 7%-31% in soils at the rates of 100-350 kg N ha 1.Nitrogen losses increased with N application rates,from 44% of the applied fertilizer N at the rate of 100 kg N ha 1 to 69% of the N applied at 350 kg N ha 1.Ammonia volatilization and apparent denitrification were the main pathways of N losses.The N application rate of 300 kg N ha 1,which is commonly used by local farmers in the study region,was found to lead to a significant reduction in economic and environmental efficiency.Considering the cost for mitigating environmental pollution and the maximum net economic income,an application rate of 100-150 kg N ha 1 would be recommended.This recommended N application rate could greatly reduce N loss from 199 kg N ha 1 occurring at the N application rate of 300 kg N ha 1 to 80-110 kg N ha 1,with the rice grain yield still reaching 7 300-8 300 kg DW ha 1 in the meantime.

碳纤维复丝拉伸强度测量不确定度评定

依据GB/T 3362-2017《碳纤维复丝拉伸性能试验方法》,测定了东丽T800HB-6000聚丙烯腈(PAN)基碳纤维复丝的拉伸强度,根据测量不确定度评估与表示理论,分析得出拉伸强度的主要测量不确定度来源为重复性测量、线密度测量、体密度测量、电子万能试验机示值误差及测量结果的数据修约。推算得出当平均拉伸强度为5256MPa时,测量结果的扩展测量不确定度为134MPa。