Araucaria cunninghamii Seedling Response to Different Forms and Rates of ^(15)N-Labelled Fertiliser

Nitrogenous fertilisers are under consideration for promoting the growth of nursery-reared hoop pine （Araucaria cunninghamii Alton ex A. Cunn） seedlings in the establishment phase of second rotation （2R） plantations. Using ^15N- labelled fertilisers, we investigated the effect of different forms （ammonium sulphate, ammonium nitrate, potassium nitrate and urea） and rates of application （0, 150 and 300 mg N kg^-1 dried soil） of fertilisers on the growth, ^15N recovery and carbon isotope composition （δ^13C） of hoop pine seedlings in a 12-month glasshouse trial in southeast Queensland, Australia. The ^15N-labelled fertilisers were applied to nursery-reared hoop pine seedlings, which were then grown in pots, containing ca. 1.2 kg dried soil, under well watered conditions for 12 months. Four seedlings from each treatment were harvested at 4-month intervals, divided into roots, stem and foliage, with a further subdivision for new and old foliage, and then analysed for ^15N, total N, δ^13C and total C. There was no significant response in the seedling growth to the form or rate of application of nitrogen （N） fertiliser within the 12-month period, indicating that the seedlings did not experience N deficiency when grown on second rotation hoop pine soils. While the combined ^15N recovery from soil and plant remained at around 70% throughout the experiment, the proportion of ^15N recovered from the plants increasing steadily over time. Nitrate containing fertilisers at 150 mg N kg^-1 soil gradually increased seedling foliage δ^13C over the 12-month period, indicating an increase in seedling water use efficiency.

Nitrogen Forms of Maillard Polymers Derived from Xylose and ^(15)N-Labelled Glycine

Water-soluble, nondialyzable Maillard polymers were prepared by reacting D-xylose with 15N-glycine (and/or glycine) at 68 ℃ and pH 8.0 at equimolar concentrations of 1, 0.5 and 0.1 mol L-1, respectively,for 13 days and partitioned into acid-insoluble (MHA) and acid-soluble (MFA) fractions. The nitrogen forms in these polymers were studied by using the 15N cross polarization-magic angle spinning nuclear magnetic resonance (CPMAS NMR) technique in combination with chemical methods. The 15N nuclear magnetic resonance (NMR) data showed that while the yield, especially the MHA/MFA ratio, varied considerably with the concentrations of the reactants, the nitrogen distribution patterns of these polymers were quite similar.From 65% to 70% of nitrogen in them was in the secondary amide and/or indole form with 24%~25% present as aliphatic and/or aromatic ammes and 5% to 11% as pyrrole and/or pyrrole-like nitrogen. More than half (50%~77%) of the N in these polymers were nonhydrolyzable. The role of Maillard reaction in the formation of nonhydrolyzable nitrogen in soil organic matter is discussed.

^(15)N同位素标记氮肥减施棉田养分利用效率分析

【目的】研究氮肥减施对棉花氮素吸收、转运及利用效率的影响,为绿洲滴灌棉田氮肥合理施用提供参考依据。【方法】利用^(15)N同位素示踪技术,采用盆栽试验,设置不施氮肥(N_(0))、氮肥减施(N_(1),225 kg/hm^(2))、当地推荐施肥(N 2,300 kg/hm^(2))3个处理,研究氮肥减施对棉花生物量、氮素吸收量、肥料氮吸收量以及氮肥利用率的影响。【结果】氮肥减施处理的棉花干物质积累量和氮素吸收量均显著高于不施氮处理(N_(0)),而与当地推荐施肥处理差异均不显著;氮肥减施处理棉花壳、籽的干物质量和籽的氮素吸收量均显著高于当地推荐施肥处理,分别增加了7.02%、6.81%和16.59%;2个施肥处理棉籽的肥料氮(^(15)N)积累量占比最高,占全株的26.02%~35.99%,其次为叶(22.40%~23.81%)和茎(14.48%~18.98%),絮中最少(3.05%~6.62%);氮肥减施处理生殖器官的肥料氮吸收量比当地推荐施肥处理高19.02%;2个施肥处理的棉株吸收的氮素来源于肥料氮的比例(Ndff%)为21.14%~21.70%;氮肥减施处理的氮肥利用率和表观利用率均显著高于当地推荐施肥处理,分别增加2.36%和3.12%。【结论】氮肥减施(225 kg/hm^(2))可以显著提高棉籽中的干物质量、氮素吸收量、肥料氮(^(15)N)吸收量、Ndff%以及棉花整株的氮肥利用率,在确保棉花产量不降低的前提下,适度的减少化肥施用量是提高化肥利用率最有效的措施之一。

基于^(15)N稳定同位素示踪技术的植物组合湿地对氨氮去除途径研究

人工湿地是生态修复受污染水体的重要手段,对氮的去除效果显著,但不同植物湿地对氮去除效果差异明显,因此不同类型植物组合后的湿地对氮去除效果及去除途径值得进一步研究。通过室内控制试验,以常见浮水植物绿狐尾藻(Myriophyllum elatinoides)和挺水植物梭鱼草(Pontederia cordata)为研究对象,利用^(15)N稳定同位素示踪技术探究绿狐尾藻、梭鱼草及绿狐尾藻+梭鱼草植物组合对氨氮(NH_(4)^(+)-N)的去除途径。结果表明,绿狐尾藻+梭鱼草植物组合处理相较于单一绿狐尾藻和梭鱼草处理对氮的脱除量分别提高1.8%和3.6%。基于^(15)N质量平衡,绿狐尾藻、梭鱼草和绿狐尾藻+梭鱼草植物组合处理氮去除途径的底泥吸附贡献分别为8.30%、7.96%和6.94%,植物吸收贡献分别为41.76%、35.34%和48.67%,微生物作用去除贡献分别为49.94%、56.71%和44.39%。微生物作用在湿地脱氮过程中占主导地位。相较于单一植物湿地,植物组合湿地对氮的去除效果得到提升,同时促进了植物对水体NH 4+-N的吸收。该研究有助于更好地理解植物组合湿地对氨氮的脱除途径。

应用^(15)N自然丰度值揭示不同氮源对设施土壤氨挥发的贡献

【目的】我国设施蔬菜生产中普遍存在着氮肥施用过量、氨气(NH_(3))挥发损失严重等问题。通过^(15)N自然丰度法,研究不同肥料类型对土壤NH_(3)挥发的影响,并定量分析其贡献率,为实现降低氮素损失的氮肥科学管理提供依据。【方法】开展为期40天的番茄盆栽培养试验,供试土壤为棕壤,未施过肥也未种植过作物,供试作物为番茄。试验设置4个处理,即不施氮肥(CK)和等量施氮(N3 g/pot)条件下单施鸡粪有机肥(M)、单施尿素(U)、有机肥半量替代尿素(MU)处理。利用被动采样器测定了土壤NH_(3)挥发速率和累积排放量,并借助^(15)N自然丰度方法估算肥料和土壤氮对NH_(3)挥发的贡献。【结果】基肥施用后3~6天内,NH_(3)挥发速率迅速增加并达到高峰,之后逐渐降低,直至第33天恢复到施肥前水平。与MU和U处理相比,M处理的净NH_(3)挥发累积量分别显著降低了60.8%和63.1%(P<0.05),MU较U处理的NH_(3)减排效果不显著(4.62%),相应的NH_(3)挥发系数分别为1.37%(U)、1.29%(MU)及0.51%(M)。施肥处理中,δ^(15)N-NH_(3)值随NH_(3)挥发的进行而迅速降低,然后逐渐增加至施肥前水平,M处理的δ^(15)N-NH_(3)均值高于MU和U处理。^(15)N同位素混合方程计算显示,在番茄生产中肥料对NH_(3)挥发的贡献比例为:M处理中鸡粪贡献30.5%,U处理中尿素贡献53.1%,MU处理中鸡粪和尿素分别贡献28.6%和56.6%。【结论】等量施氮条件下,单施鸡粪产生的NH_(3)挥发量远低于尿素,鸡粪和尿素等量氮配施对NH_(3)挥发的减排效果不显著。根据同位素分馏效应计算结果,单施鸡粪、尿素对土壤NH_(3)挥发源的贡献比例分别为30.5%、53.1%,鸡粪和尿素配施时二者对土壤NH_(3)挥发源的贡献比例分别为28.6%、56.6%,贡献比例与单施差异不大。因此,控制化肥氮施用量是减少NH_(3)挥发的关键。

二氧化碳倍增对植物叶片^(15)N自然丰度的影响

大气CO_(2)浓度上升通常会提高植物生产力并伴随叶片氮含量的下降。然而大气CO_(2)如何影响叶片^(15)N丰度及其相关机理还不清楚。以小麦和向日葵为实验材料,测定了两个CO_(2)浓度(410与820μmol•mol^(-1))处理下叶片的氮同位比值(δ^(15)N)和氮含量。结果表明:小麦和向日葵叶片氮含量随CO_(2)浓度升高呈下降趋势,然而δ^(15)N对CO_(2)浓度倍增的响应存在差异。在高CO_(2)浓度处理下小麦叶片δ^(15)N显著下降6.5‰,而向日葵叶片δ^(15)N小幅上升2.1‰,且叶片和地上部生物量显著增加。基于此,小麦的氮营养特征符合氮同化受限假说,而向日葵符合稀释效应假说。小麦叶片δ^(15)N随叶龄或者细胞年龄的增加而显著下降,因此在利用^(15)N来研究植物氮代谢时需要区分叶龄的影响。整合分析结果表明,CO_(2)浓度升高导致非豆科C_(3)植物的δ^(15)N显著下降达0.3‰,与小麦的研究结果相符。综上所述,限制硝态氮同化是CO_(2)影响植物氮代谢和^(15)N丰度的重要机制。

丛枝菌根对植物叶片δ^(15) N含量影响的数据挖掘分析

为明确丛枝菌根(AM)对植物叶片稳定氮同位素(δ^(15)N)含量的影响,探索丛枝菌根在调控植物应对全球变化方面的重要功能,通过数据挖掘,建立了AM植物和非AM(non-AM)植物叶片δ^(15)N含量数据库,探究了AM对植物叶片δ^(15)N含量的影响。结果表明:AM植物叶片δ^(15)N含量为0.86‰,显著高于non-AM植物叶片的0.50‰。丛枝菌根针对不同植物功能群而言,将植物的AM状况与植物的固氮状况和生长周期结合作为影响因素时,AM都显著影响着植物叶片的δ^(15)N含量。虽然AM没有显著提高固氮植物叶片δ^(15)N含量,但却把非固氮植物叶片δ^(15)N的含量从0.58‰提高到了0.99‰。AM使多年生植物叶片δ^(15)N含量的增加最显著,从0.49‰增加到了0.82‰。可见,丛枝菌根作为与植物长期共生进化的最广泛共生体,对植物叶片δ^(15)N含量有不同程度的影响。

Estimates on nitrogen uptake in the subsequent wheat by aboveground and root residue and rhizodeposition of using peanut labeled with^(15)N isotope on the North China Plain

Leguminous crops play a vital role in enhancing crop yield and improving soil fertility. Therefore, it can be used as an organic N source for improving soil fertility. The purpose of this study was to(i) quantify the amounts of N derived from rhizodeposition, root and above-ground biomass of peanut residue in comparison with wheat and(ii) estimate the effect of the residual N on the wheat-growing season in the subsequent year. The plants of peanut and wheat were stem fed with 15 N urea using the cotton-wick method at the Wuqiao Station of China Agricultural University in 2014. The experiment consisted of four residue-returning strategies in a randomized complete-block design:(i) no return of crop residue(CR0);(ii) return of above-ground biomass of peanut crop(CR1);(iii) return of peanut root biomass(CR2); and(iv) return of all residue of the whole peanut plant(CR3). The 31.5 and 21% of the labeled 15 N isotope were accumulated in the above-ground tissues(leaves and stems) of peanuts and wheat, respectively. N rhizodeposition of peanuts and wheat accounted for 14.91 and 3.61% of the BG15 N, respectively. The 15 N from the below-ground 15 N-labeled of peanuts were supplied 11.3, 5.9, 13.5, and 6.1% of in the CR0, CR1, CR2, and CR3 treatments, respectively. Peanut straw contributes a significant proportion of N to the soil through the decomposition of plant residues and N rhizodeposition. With the current production level on the NCP, it is estimated that peanut straw can potentially replace 104 500 tons of synthetic N fertilizer per year. The inclusion of peanut in rotation with cereal can significantly reduce the use of N fertilizer and enhance the system sustainability.

Application of ^15N Stable Isotope Labeling Technology in Sugarcane Nitrogen Research

Nitrogen is one of the essential nutrient elements for plant growth,which plays an important role in the growth and development of sugarcane. The whole growth cycle of sugarcane needs a large amount of nitrogen. Increasing the application of nitrogen can improve the yield of sugarcane,but it will also cause environmental pollution. Therefore,how to control or reduce the application of nitrogen fertilizer while continuously increasing sugarcane yield,reduce the increase of sugarcane production cost and environmental pollution caused by excessive application of nitrogen fertilizer has become an important scientific problem faced by sugarcane industry in China.^15N stable isotope labeling technology has been applied to many crops as a nitrogen research tool. In order to better understand the demand of nitrogen fertilizer in soil-cane system,this paper reviewed nitrogen allocation in plants,nitrogen loss,nitrogen recycling and endogenous nitrogen fixation of sugarcane based on^15N stable isotope labeling technology used in the nitrogen uptake and utilization,providing a theoretical basis for the improvement of sugarcane nitrogen use efficiency and the efficient nitrogen fertilizer management of sugarcane.

The fate of ^(15)N-labeled nitrogen inputs to pot cultured beech seedlings

The partitioning of nitrogen deposition among forest soil （including forest floor）, leachate and above- and belowground biomass of pot cultured beech seedlings in comparison to non-cultured treatments were investigated by adding 1.92 g.m^-2 ^15N tracer in throughfall for two successive growing seasons at a greenhouse experiment. Ammonium and nitrate depositions were simulated on four treatments （cultured and non-cultured） and each treatment was labeled with either ^15N-NH4^＋ or ^15N-NO3^-. Total recovery rates of the applied ^15N in the whole system accounted for 74.9% to 67.3% after ^15N-NH4^＋ and 85.3% to 88.1% after ^15N-NO3^-in cultured and non-cultured treatments, respectively. The main sink for both ^15N tracers was the forest soil （including forest floor）, where 34.6% to 33.7% of ^15N-NH4^＋ and 13.1% to 9.0% of ^15N-NO3^-were found in cultured and non-cultured treatments, respectively, suggesting strong immobilization of both N forms by hetero- trophic microorganisms. Nitrogen immobilization by microorganisms in the forest soil （including forest floor） was three times higher when ^15N-NH4^＋ was applied compared to ^15N-NO3^-. The preferential heterotrophic use of ammonium resulted in a two times higher retention of deposited ^15N-NH4^＋ in the forest soil as compared to plants. In contrast, nitrate immobilization in the forest soil was lower compared to plants, although statistically it was not significantly different. In total the immobilization of ammonium in the plant-soil system was about 60% higher than nitrate, indicating the importance of the N-forms deposition for retention in forest ecosystems.

甜樱桃对^15N尿素的吸收、分配和利用特性

以5年生‘早大果’甜樱桃为试材,研究了其在萌芽前土施15N尿素的吸收、分配和利用特性.结果表明:植株器官从肥料中吸收分配到的15N量对该器官全氮量的贡献率(Ndff)均随时间推移逐渐升高,盛花期细根和贮藏器官的Ndff较高;果实硬核期,新生器官中长梢和长梢叶的Ndff增长迅速,分别达0.72%和0.59%;果实硬核期到采收期,果实的Ndff增长迅速,到采收期达到最高,为1.78%;果实采收后到花芽分化期,新生器官Ndff增长减慢而贮藏器官增长迅速.盛花期根系吸收的氮素首先分配到贮藏器官,粗根15N分配率最高,为54.91%;果实硬核期细根和贮藏器官15N分配率由盛花期的85.43%下降到55.11%,而地上部新生器官则升高至44.89%;果实采收期15N分配率变化不大,果实采收后氮素营养迅速向贮藏器官中运转,花芽分化期细根和贮藏器官的15N分配率升高至72.26%,而地上部新生器官15N分配率与采收期相比下降了19.31%.从盛花期到花芽分化期,植株对15N尿素的当季利用率呈升高趋势,于花芽分化期达到最高,为16.86%.

不同施肥期沾化冬枣对^(15)N的吸收、分配及利用特性

盆栽条件下利用15N示踪技术,研究不同时期施15N-尿素,对沾化冬枣15N的吸收利用及分配特性的影响。结果表明:生长季前期(萌芽前和花前)施用15N-尿素,经根系吸收后,15N优先分配到贮藏器官(包括主干、多年生枝和粗根)中,然后外运用于树体新生器官(包括枣吊及其叶片、新生营养枝、细根及果实)的形成,果实采收后15N开始向贮藏器官回流;果实硬核期15N直接用于树体营养生长和生殖生长,而不是先贮藏再利用;果实速长期15N优先向贮藏器官中积累;萌芽前施15N在树体内的运转规律符合落叶果树贮藏N营养分配规律,优先转运到生长中心。随着施肥期的后延,植株对15N-尿素的当季利用率逐渐下降。

用^(15)N叶片标记法研究旱作水稻与花生间作系统中氮素的双向转移

在盆栽条件下 ,采用 1 5N叶片富积标记方法 ,研究了旱作水稻与花生间作系统氮素的双向转移及供氮水平对氮素转移的影响。结果表明 :在 15 kg hm- 2、75 kg hm- 2、 15 0 kg hm- 2等 3个氮肥水平下 ,间作水稻的干物质生物量和氮素吸收量分别为9.4 1g株 - 1、12 .0 6 g株 - 1、13.5 3g株 - 1和 2 0 7.35 mg株 - 1、2 4 1.81mg株 - 1、2 5 9.37mg株 - 1 ,分别比单作水稻增加了 2 1%～ 2 9%、7%～ 2 9%、18%～ 30 %和 4 3.4 3%、4 5 .72 %、32 .81% ,间作对水稻的干物质积累和氮素吸收量有显著促进作用。间作和单作系统中花生的干物质生物量和氮素吸收量间的差异均不显著 ;用花生叶片标记 1 5N试验表明 ,在 3个氮肥水平下花生体内的氮素中分别有 9.93%、5 .6 5 %、4 .2 2 %转移到了水稻植株体内 ,其转移量随土壤氮素水平的提高而降低 ;用水稻叶片标记 1 5N则分别有 4 .39%、2 .0 6 %、1.38%的水稻体内氮素转移到了花生植株体内 ,其转移量也随土壤氮素水平的提高而降低 ;用 1 5N叶片标记的方法证明花生与水稻旱作的间作系统中存在着氮素的双向转移 ,但净转移方向是由花生植株向水稻的氮素转移。对豆科与禾本科间作系统中氮素转移的机理、途径也做了分析和讨论。

应用^(15)N研究施氮比例对小麦氮素利用的效应

应用1 5N示踪技术研究氮素不同底施和追施比例对小麦氮素利用的效应。结果表明 ,籽粒蛋白质含量随追施氮肥比例的增加而提高 ,颖壳、根系、茎秆的含氮量也呈随追氮比例增加而提高的趋势。收获时植株各器官中 ,籽粒含氮量最多 ,依次为颖壳、叶片、茎秆、根系。在两种肥料的比较中 ,施用尿素比硫酸铵在植株营养器官中残留量少 ,而籽粒中氮素吸收量大。各器官NDFF % (氮素来自肥料氮的百分比 )随追肥比例增加而呈低高低的变化曲线。均可用Y =a +bx +cx2 (Y =NDFF ,x =处理代号 )方程表示。

应用^15N示踪技术研究水稻对氮肥的吸收和分配

运用15N示踪技术研究了不同生育时期水稻对肥料氮的吸收和分配。结果表明:15N分别标记基肥(N1)、分蘖肥(N2)和拔节孕穗肥(N3)处理中,水稻吸收的氮素在分蘖盛期、拔节孕穗期和开花期分别有23.1%、8.3%和19.9%来自肥料;从开花期到成熟期,不同时期标记的15N转运量大小为:拔节孕穗期追肥(N3)>基肥(N1)>分蘖期追肥(N2),但基肥的氮素转运效率最高,其他两次追肥氮素转运效率相当;在成熟期,N1、N2、N3处理残留在稻草中的15N分配比例分别为24.3%、26.7%和30.4%。无论是氮肥基施,还是分蘖期或拔节孕穗期追肥,水稻开花期之前所吸收的15N主要分配在叶片中,其次是鞘,再次是茎,开花期后,随着15N从营养器官向籽粒中的转移,叶片、茎秆和鞘中的15N分配百分比逐渐下降,籽粒15N的分配百分比逐渐上升。试验结果还显示,基肥15N标记时,分蘖盛期所吸收的氮来自肥料最高,为23.1%,随生育期的推进逐渐下降,到成熟期仅为10.6%,成熟期吸收的氮来自分蘖期和拔节孕穗期追施的氮肥分别为5.9%和12.4%。表明(1)当土壤氮素含量不高时,基肥对水稻整个生育期生长很重要,基肥适量增加可显著增加水稻茎蘖数,对水稻群体质量建成有决定作用;(2)拔节孕穗肥可显著促进水稻生育后期的籽粒灌浆和充实,增加拔节孕穗期的氮素供应,有利于提高水稻的氮素收获指数;(3)分蘖期追肥氮素损失较大,水稻吸收较少,可以适量增加水稻基肥而不施分蘖肥,或在水稻分蘖后期水稻生物量较大时适量施肥以促进水稻吸收。

应用^(15)N、^(32)P示踪法研究双季稻一次性全层施肥技术的肥料效应

试验在双季高产稻区湖南醴陵市大田条件下进行。为比较一次性施肥技术与高效施肥技术肥料效应的差异 ,应用15N和3 2 P双标记研究了一次性施肥法的肥料效应 ,结果表明 :与对照法相比 ,一次性施肥技术可以促进水稻前中期对养分的吸收和增加干物质的积累量 ,全生育期水稻对氮和磷肥的利用率、氮肥回收率、水稻生物产量及谷物产量与对照相当。但由于一次性施肥法操作简单 ,有利于双季稻大面积平衡增产 。

地下水中NO_3^-的^(15)N和^(18)O同位素测试新技术——密封石英管燃烧法

近40年来,硝酸盐(NO-3)已成为最普遍的地下水污染源之一。在本文中,介绍了在野外用阴离子交换树脂收集地下水中的NO-3的新技术;用AgNO3和氧化铜丝及铜颗粒燃烧反应测定氮同位素比值;用AgNO3+C(石墨)测定NO-3中氧同位素比值的密封石英管燃烧法,它们是1995年以后发展起来的最新测试技术。

设施栽培油桃对叶面施^(15)N的吸收、分配特性研究

以设施栽培的5年生早红珠油桃/山毛桃为试材,应用15N示踪技术研究油桃叶片对15N-尿素的吸收及运转特性。结果表明,叶片施用15N-尿素标记叶吸收主要发生在叶片涂抹15N-尿素后6 h内,平均吸收速率为0.204mg/(g.h);标记叶中15N吸收量24 h达到最高,新梢和梢顶嫩叶15N含量在施用15N-尿素48 h达到最高,下部叶15N含量很低,没有明显的峰;处理168 h各器官中15N含量为标记叶>梢顶嫩叶>新梢>下部叶;试验结束时分配势Ndff(即各器官N含量来自化肥N所占的百分率)为标记叶中最高,然后依次为梢顶嫩叶、新梢、下部叶。这说明氮素迅速被吸收并运到嫩梢和嫩叶中,从而促进这些新生器官的形态建造,可起到以N增C的作用。不同叶面处理的试验还表明,正面和背面全部涂抹的叶片15N含量最高,只涂抹叶片背面次之,涂抹正面最低。设施栽培油桃叶片可迅速吸收尿素,其吸收量早晨明显优于中午和下午,因此设施油桃栽培管理中于早晨进行叶面施尿素,且正反面兼顾,N素的吸收利用效果最好。

^(15)N标记羊粪和稻草还田氮素的转化和效应的研究

本工作通过田间微区试验，研究了^（１５）Ｎ标记羊粪和稻草单独施用或分别与尿素配合施用作为水稻基肥时，肥料氮的命运及其对水稻产量的影响。结果表明，羊粪单施或与化肥Ｎ配合施用时，稻谷回收的羊粪Ｎ分别为７．９％和９．２％，相当于饲料稻草Ｎ的２．２％和２．６％，若将羊体中回收的饲料稻草Ｎ量（３１．２％）￣［６］计入，则羊体和稻谷共回收饲料稻草Ｎ分别为３３．４％和３３．７％，明显高于稻草直接还田时稻谷对稻草Ｎ的回收率（单施和与化肥配合施用时分别为９．９％和１４．５％）。稻草喂羊，再以其粪尿还田，其经济效益也明显高于稻草直接还田。

^(15)N示踪不同施氮量对超级稻产量形成及氮素吸收的影响

为探讨施氮量对超级稻产量、光合作用以及氮肥利用率的影响,以杂交稻品种两优培九、Y两优1号,常规稻品种玉香油占、黄花占为材料,采用15N示踪法进行了5种施氮量处理的大田盆栽试验。结果表明,增加施氮量提高了SPAD值和光合速率,品种间表现一致。拔节期以后,SPAD值呈现高-低-高的变化趋势,叶片光合速率品种间有差异,杂交稻呈线性下降变化趋势,常规稻呈线性下降后略有回升。随施氮量增加,稻草中氮素含量杂交稻比常规稻低,分别为0.72%~0.78%和0.59%~0.61%;而稻谷中差异不显著。供试品种的产量、氮肥利用率对施氮量的反应分别表现为先增后稳和先增后减的非线性变化趋势,其中以施氮量为150 kg·hm-2处理的氮素利用率最高,杂交稻为33.9%~34.6%,常规稻为33.8%~34.2%,但杂交稻产量显著高于常规稻,平均增产16.4%。可见,随施氮量增加,杂交稻更多的将稻草中的氮素通过光合作用转移到稻谷中,常规稻则是将更多的营养积累在稻草中。本研究为杂交稻高产与氮高效协调栽培提供了理论依据。