Soil Nitrogen Distribution and Plant Nitrogen Utilization in Direct-Seeded Rice in Response to Deep Placement of Basal Fertilizer-Nitrogen

Deep placement of controlled-release fertilizer increases nitrogen (N) use efficiency in rice planting but is expensive. Few studies on direct-seeded rice have examined the effects of deep placement of conventional fertilizer. With prilled urea serving as N fertilizer, a two-year field experiment with two N rates (120 and 195 kg/hm2) and four basal N application treatments (B50, all fertilizer was broadcast with 50% as basal N;D50, D70 and D100 corresponded to 50%, 70% and 100% of N deeply placed as basal N, respectively) were conducted in direct-seeded rice in 2013 and 2014. Soil N distribution and plant N uptake were analyzed. The results showed that deep placement of basal N significantly increased total N concentrations in soil. Significantly greater soil N concentrations were observed in D100 compared with B50 at 0, 6 and 12 cm (lateral distance) from the fertilizer application point both at mid-tillering and heading stages. D100 presented the highest values of dry matter and N accumulation from seeding to mid-tillering stages, but it presented the lowest values from heading to maturity stages and the lowest grain yield for no sufficient N supply at the reproductive stage. The grain yield of D50 was the highest, however, no significant difference was observed in grain yield, N agronomic efficiency or N recovery efficiency between D70 and D50, or between D70 and B50, while D70 was more labor saving than D50 for only one topdressing was applied in D70 compared with twice in other treatments. The above results indicated that 70% of fertilizer-N deeply placed as a basal fertilizer and 30% of fertilizer-N topdressed as a panicle fertilizer constituted an ideal approach for direct-seeded rice. This recommendation was further verified through on-farm demonstration experiments in 2015, in which D70 produced in similar grain yields as B50 did.

Effects of mechanized deep placement of nitrogen fertilizer rate and type on rice yield and nitrogen use efficiency in Chuanxi Plain, China

This paper investigates the yield and nitrogen use efficiency (NUE) of machine-transplanted rice cultivated using mechanized deep placement of N fertilizer in the rice–wheat rotation region of Chuanxi Plain,China.It provides theoretical support for N-saving and improves quality and production efficiency of machine-transplanted rice.Using a single-factor complete randomized block design in field experiments in 2018 and 2019,seven N-fertilization treatments were applied,with the fertilizer being surface broadcast and/or mechanically placed beside the seedlings at (5.5±0.5) cm soil depth when transplanting.The treatments were:N0,no N fertilizer;U1,180 kg N ha^(–1) as urea,surface broadcast manually before transplanting;U2,108 kg N ha^(–1) as urea,surface broadcast manually before transplanting,and 72 kg N ha^(–1) as urea surface broadcast manually on the 10th d after transplanting,which is not only the local common fertilization method,but also the reference treatment;UD,180 kg N ha^(–1) as urea,mechanically deep-placed when transplanting;M1,81.6 kg N ha^(–1) as urea and 38.4 kg N ha^(–1) as controlled-release urea (CRU),mechanically deep-placed when transplanting;M2,102 kg N ha^(–1) as urea and48 kg N ha^(–1) as CRU,mechanically deep-placed when transplanting;M3,122.4 kg N ha^(–1) as urea and 57.6 kg N ha^(–1) as CRU,mechanically deep-placed when transplanting.The effects of the N fertilizer treatments on rice yield and NUE were consistent in the 2 yr.With a N application rate of 180 kg ha^(–1),compared with U2,the N recovery efficiency (NRE),N agronomic use efficiency (NAE) and yield under the UD treatment were 20.6,3.5 and 1.1% higher in 2018,and 4.6,1.7 and 1.2% higher in 2019,respectively.Compared with urea alone (U1,U2 or UD),the NRE,NAE and yield achieved by M3 (combined application of urea and controlled-release urea) were higher by 9.2–73.3%,18.6–61.5% and 6.5–16.5%(2018),and 22.2–65.2%,25.6–75.0% and 5.9–13.9%(2019),respectively.Compared with M3,the lower-N treatments M1 and M2 significantly increased NRE by 4.0–7.8% in 2018 and 3.1–4.3% in 2019,respectively.Compared with urea surface application (U1 or U2),the yield under the M2 treatment was higher by 4.3–12.9% in 2018 and 3.6–10.1% in 2019,respectively.Compared with U2,the NRE and NAE under the M2 treatment was higher by 36.9 and 36.3% in 2018,and 33.2 and 37.4% in 2019,mainly because of higher N uptake.There was no significant difference in the concentration of nitrate in the top 0–20 cm soil under U1,U2 and M2 treatments during the full heading and maturity stages.During the full heading stage,U2 produced the highest concentration of nitrite in 0–20 cm and 20–40 cm soil among the N fertilizer treatments.In conclusion,mechanized deep placement of mixed urea and controlled-release urea (M2) at transplanting is a highly-efficient cultivation technology that enables increased yield of machine-transplanted rice and improved NUE,while reducing the amount of N-fertilization applied.

Effect of side deep placement of nitrogen on yield and nitrogen use efficiency of single season late japonica rice

Side deep placement of nitrogen plays an important role in improving rice yield and nitrogen use efficiency.Few studies have examined the effects of reducing the times of nitrogen(RTN)application and reducing the nitrogen rate(RNR)of application on rice yield and nitrogen use efficiency under side deep placement of nitrogen in paddy fields.Therefore,a field experiment of RNT and RNR treatments was conducted with nine fertilization modes during the 2018–2019 rice growing seasons in a rice–wheat cropping system of the lower reaches of the Yangtze River,China.Rice yield and nitrogen use efficiency were investigated under side deep placement of nitrogen.We found that under the same nitrogen application rate,the yield of RTN3 increased by 9.64 and 10.18%in rice varieties NJ9108 and NJ5718,respectively,compared with the farmers’fertilizer practices(FFP).The nitrogen accumulation of RTN3 was the highest at heading stage,at 11.30 t ha^(–1)across 2018 and 2019.Under the same nitrogen application rate,the N agronomic use efficiency(NAE),N physiological efficiency(NPE)and N recovery efficiency(NRE)of RTN3 were 8.1–21.28%,8.51–41.76%and 0.28–14.52%higher than those of the other fertilization modes,respectively.RNR led to decreases in SPAD value,leaf area index(LAI),dry matter accumulation,nitrogen accumulation,and nitrogen use efficiency.These results suggest that RTN3 increased rice yield and nitrogen use efficiency under the side deep placement of nitrogen,and RNR1 could achieve the goals of saving cost and increasing resource use efficiency.Two fertilization modes RTN3 and RNR1 both could achieve the dual goals of increasing grain yield and resource use efficiency and thus are worth further application and investigation.

减氮和侧深基施缓混肥对‘南粳5055’产量、品质及氮素吸收利用的影响

旨在探讨减氮和侧深基施缓混肥对水稻产量、品质和氮素吸收利用的影响,本研究以当地主推粳稻‘南粳5055’为材料,设置不施氮肥(0N)、当地常规施肥(CK)、一次性侧深基施缓混肥(S1)、侧深基施缓混肥+追施速效氮肥(S2) 4个处理,分别在如皋市东陈镇和白蒲镇两地的水稻田开展试验。两地的试验结果均表明:与CK相比,在减氮25%情况下,S1和S2均明显改善了稻米的外观品质和蒸煮食味品质,但两者的水稻产量和总吸氮量均有所降低,平均分别减少了5.12%、1.27%和9.53%、2.77%。其中S1明显减产主要由于每穗粒数的显著降低,而S2则与CK无显著差异。另外,S2也较CK显著提高了氮肥的吸收利用率、农学效率和偏生产力。表明在氮肥大幅减少的情况下,采用侧深基施缓混肥+追施速效氮肥更有利于实现水稻的绿色优质高效生产。

侧深施肥装置三通管气固两相流仿真与试验

为探究气吹式侧深施肥装置三通管不同结构特征对气流和肥料颗粒运动的影响,通过理论分析,设计气流入口与出口轴线垂直的a型三通管、气流入口与出口轴线呈45°夹角的b型三通管、气流入口与出口同轴的c型三通管。在三通管内径为28 mm、通入气流速度为16.4 m/s、肥料颗粒流量为20 g/s的条件下,采用CFD-EDM耦合方式对不同管道内气流、压力、颗粒运动状态进行仿真分析。结果表明:气流经a、b、c三种类型三通管产生不同的流动效果,进而影响肥料颗粒运动特性,颗粒最大运动速度分别为1.99 m/s、2.94 m/s、2.07 m/s,期间颗粒产生最大碰撞力分别为0.05 N、0.13 N、0.34 N。通过验证试验对比表明,采用b型管侧深施肥装置排肥稳定性变异系数为0.81,肥料破损率为0.72%,施肥过程中无肥料堵塞。

新型高效绿色氮肥管理对水稻产量形成与氮素利用及氨挥发损失的影响

通过大田试验采用随机区组设计,设置7种施氮处理,即不施氮肥(CK)、农民常规施肥(FFP)、脲酶抑制剂型氮肥并减氮21.40%(与FFP比,余同)(OPT)、一次性机械侧深施树脂包膜尿素并减氮35.70%(CRUM1)、一次性机械侧深施肥包肥并减氮35.70%(CRUM2)、一次性穴施树脂包膜尿素并减氮51.80%(CRUR1)、一次性穴施肥包肥并减氮51.80%(CRUR2),测定不同施氮处理下水稻株高、分蘖、干物质量、产量、氮素利用效率以及氨挥发损失等,以探究新型氮肥管理方式对水稻产量、氮素利用效率和氮挥发损失的影响。结果表明,CRUM1和CRUM2处理株高和分蘖数与FFP处理相当;与传统撒施(CK、FFP和OPT,下同)相比,CRUM1和CRUM2干物质积累量提高11.90%~12.30%;根据水稻氮素营养指数(NNI),机械侧深施氮能满足水稻生长对氮素的需求。水稻侧深施和穴施在减氮35.70%~51.80%的情况下也可高产稳产(9.76 t/hm2和9.60 t/hm^(2))。与传统撒施相比,机械侧深施和穴施的田面水NH_(4)^(+)-N较低,氨挥发损失降低39.15%~93.15%,氮素利用效率提高77.45%~95.70%。可见,优化氮肥管理可以实现水稻在减氮情况下稳产,同时提高氮素利用效率和减少氨挥发,其中机械侧深施和穴施配合新型氮肥可减少氮肥投入35.70%~51.80%。

侧深施肥对水稻产量及养分吸收的影响

肥料深施是提高粮食产量和氮素利用率的关键要素。鉴于当前临海地区化肥种类繁多、施肥方式多样,通过田间试验,研究不同肥料与不同施肥方式相结合对水稻产量及土壤肥力的影响。结果表明,惠多利复合肥深施(HS)和惠多利复合肥减量深施(HSJ)对水稻增产效果明显;茂施缓释肥一次性深施(MSY)显著增加了稻谷含氮量。因此,水稻产量及养分吸收受肥料类型和施肥方式的影响较大。茂施缓释肥减量深施(MSJ)提升pH值的同时也显著提升了土壤有机质、全氮、有效磷、速效钾含量。综上所述,HS和HSJ施肥处理的株高和穗长增效显著且显著提升水稻产量,建议在后续生产中进行推广。

侧深施氮对我国水稻产量和氮利用效率影响的整合分析

探讨在不同条件下侧深施氮(SDN)对水稻产量及氮肥利用效率的影响,为水稻精准施氮提供理论依据。通过搜集已发表的文献,建立了214组SDN和农民常规撒施(BN)下水稻产量和氮肥利用效率的数据库。采用整合分析的方法,研究在水稻种植区、土壤氮素含量、不同施氮量等条件下SDN对水稻产量及氮肥利用效率的提升幅度,采用随机森林方法明确了影响SDN效果的主控因素。相对于BN,SDN能够显著提高产量、氮肥偏生产力、氮肥农学利用率和氮肥吸收利用率,提高幅度分别为4.57%、4.57%、23.94%和21.11%。不同种植区域下SDN对产量的提升幅度东北稻区最大。不同水稻类型下SDN的产量和氮肥利用效率提升幅度不同,产量提升方面,粳稻(6.85%)>籼稻(5.11%),杂交稻无显著提升;SDN对氮肥农学利用率和吸收利用效率的提升幅度方面,籼稻>粳稻>杂交稻。不同种植模式下SDN对产量和氮肥利用效率的提升幅度均为单季稻>双季稻。土壤全氮<2 g/kg、速效氮<150 mg/kg时SDN对产量的提升幅度较大。当SDN的氮肥施用量≤150 kg/hm^(2)和追肥施氮均使水稻产量和氮肥利用效率提升幅度较大,然而,随着SDN施氮量的提升,增产增效幅度下降。随机森林分析结果表明SDN对水稻产量的提高幅度主要受土壤全氮、有效磷和施氮量的影响,而其对水稻氮肥利用效率的提升幅度主要受速效氮、施氮量和有效磷的影响。SDN对水稻产量和氮肥利用效率均有显著的提高,南方稻区和长江流域采取SDN对产量和氮素利用效率增幅不如东北稻区,SDN有利于含氮量较低的土壤水稻增产增效,且SDN施氮量不宜超过150 kg/hm^(2),增效型氮肥、追施氮肥以及磷肥与SDN配合施用利于增产增效。

水稻机插侧深施肥减氮增效效应研究

本研究采用水稻机插侧深施缓释肥技术,探究不同施肥量和施肥方式对南粳5055的产量构成因素、茎蘖动态和经济效益的影响,以探索适合本地种植大户的施肥方式。结果表明:与常规施肥方式对比,侧深施肥能有效提高肥料的利用率、结实率、穗粒数、经济效益,但是降低了成穗率;在总施氮量相同,缓释肥侧深施肥量不同的情况下,一次性施肥的成本最高,产量最低,随着缓释肥用量减少,成本降低,缓释肥侧深施420 kg·hm^(-2),分蘖肥追施速效氮肥,穗期施用复合肥的施肥模式,效益能达最大。

侧深施肥对机插稻产量及效益的影响

为提高海陵区水稻种植水平和生产效益,提高氮肥利用率,降低肥料使用量,以海陵区主栽品种南粳9108作为供试水稻品种,设置不施氮肥对照、常规施肥、侧深一基一追施肥和侧深一次性施肥4个处理开展田间试验,研究侧深施肥对机插稻产量和效益的影响。结果表明,在机插稻侧深一基一追施肥条件下,施纯N 240 kg/hm^(2)时,水稻产量最高,为9684.00 kg/hm^(2);效益最高,为24205.20元/hm^(2)。

水稻机插秧同步侧深施肥技术

《“十四五”湖南省种植业发展规划》指出,为保障粮食安全稳定供给,加快农业转型升级,实现农药化肥减量增效目标,推进农机农艺融合,促进农业高质量发展。在此背景下,推广应用水稻机插秧同步侧深施肥技术势在必行。概述了水稻机插秧同步侧深施肥技术的特点与优势,探讨了水稻机插秧同步侧深施肥的关键技术。

水稻侧深施肥及无人机喷施技术推广应用分析

对港南区水稻侧深施肥及无人机喷施技术模式、取得成效及主要做法进行简单介绍,分析技术推广中所面临的挑战,提出加大物资补助发挥政府主导作用、加强学习与培训提高农民意识、建立示范区发挥示范带动、引导相关部门对机具设备、高效适用新型肥料的研发生产4个方面建议,并对其应用前景进行分析。

穴式苗-肥同施水稻侧深施肥装置设计与试验

为解决水稻侧深施肥作业相邻秧苗间化肥利用率低的问题,结合穴施肥农艺方法,设计了间歇定点穴式水稻侧深施肥装置.该装置采用垂直螺旋搅龙强排固体颗粒肥,依据预设的插秧与施肥动作之间的延时,控制步进电机的启停实现间歇的排肥动作,进一步控制螺旋搅龙的旋转角度,从而保证定点精量排肥.应用EDEM软件对穴式水稻侧深施肥装置进行仿真试验及分析,以行进速度、排肥能力、施肥高度为试验因素,以施肥位置合格率和排肥稳定性为响应指标,对装置排肥性能进行三因素五水平正交旋转组合试验,并使用Design-Expert软件对试验结果进行方差分析和响应面分析,获得最优解为行进速度0.47 m/s、排肥能力2.69 g/r、施肥高度16.7 mm,施肥位置合格率93.02%和排肥稳定性6.52%.以最优解为试验参数进行台架试验,验证得到施肥位置的合格率为91.23%和排肥稳定性为7.15%,与优化结果基本一致,满足穴式水稻侧深施肥的农艺要求.

高茬黏重稻茬田油菜直播埋茬防堵深施肥复合装置研究

针对长江中下游稻油轮作区油菜直播作业时,因土壤黏重板结,地表前茬水稻留茬高、留存秸秆量大,导致旋耕部件易缠绕,秸秆埋覆率低,致使深施肥铲易挂草壅堵,作业厢面拖堆不平,难以实现深施肥作业。本文设计一种适应高茬黏重稻茬田的油菜直播埋茬防堵深施肥复合作业装置,确定埋茬防堵部件深旋弯刀、浅旋弯刀、防堵直刀和深施肥铲的结构参数及刀片和深施肥铲排列安装方式。利用EDEM仿真分析了机具作业后的秸秆埋覆、空间分布及颗粒肥料深施后的分布深度,结果表明:作业速度为2.5 km/h、耕作深度为150 mm、埋茬防堵部件刀辊转速为345 r/min时,秸秆埋覆率为86.53%、施肥深度为83~106 mm。开展了油菜直播机4种田间作业工况验证试验,结果表明:埋茬防堵深施肥复合作业装置田间作业性能良好,实现了肥料深施,秸秆埋覆率为86.69%~90.35%、厢面平整度为16.48~22.65 mm、施肥深度为87.4~109.5 mm、碎土率为81.24%~92.13%。

与水稻插秧同步的螺旋推运式侧向深施肥装置的设计

目前,我国水稻生产过程中的施肥环节很大程度上沿用手工抛撒施肥方式,存在浪费肥料、农民劳动强度高、污染生活水源等问题。为此,结合农艺要求,进行了水稻螺旋推运式侧向深施肥装置的整体结构及部件设计、主要工作部件性能试验及整机性能试验。细致介绍了整体结构及关键主要工作部件的结构和参数以及田间试验情况。经过大量实际田间插秧、侧向施肥作业考核装置性能,通过分析试验数据得知:与水稻插秧同步的螺旋推运式侧向深施肥技术及装置是对传统水稻施肥模式的一次变革,能把颗粒肥料精准、定量施入水稻秧苗根系测深位置,相比传统施肥量节省约20%以上,极大提高了肥料利用率,降低了化肥对周边河流的污染程度。

水稻高速插秧机固体颗粒肥料变量施肥装置设计与试验

变量施肥技术是实施科学施肥的重要手段,可使施肥更精准、更有针对性,有效减少农田污染。在水稻高速插秧与同步施肥作业时,施肥量的调节主要采用提前标定方式调控,其调控费时、精度不稳定。为快速准确地调节施肥量,实现变量施肥作业,本文设计了一种自动控制的固体颗粒肥料变量施肥装置,阐述了变量施肥装置总体结构和工作原理,进行了关键部件设计与试验;以单片机STM32为控制核心,构建了施肥量在线检测及智能调控系统。采用试验设计优化方法,对肥料流量在线检测系统性能与主要影响因素进行试验,确定了最佳因素组合;通过试验分别构建了3种主要固体颗粒肥料检测流量与压电片电压之间的关系模型、3种主要固体颗粒肥料实际流量与排肥轴转速之间的关系模型、排肥轴转速与电动推杆工作长度和插秧机前进速度之间的关系模型,并对模型进行试验验证与分析。开展了排肥轴转速分别为20、25、30 r/min肥料质量检测精度试验,当插秧机前进速度为1 m/s匀速条件下,3种肥料总体质量检测精度平均值分别为94.45%、93.85%和93.15%;进行了复合肥施肥量为200、250、300 kg/hm~2和尿素施肥量为165、195、225 kg/hm~2调控性能试验,当插秧机前进速度为0.6~1.4 m/s条件下,3种肥料总体施肥量变异系数平均值分别为3.02%、3.15%和2.82%;进行了施肥量分别为180、225 kg/hm~2的田间试验,当插秧机前进速度为1~1.4 m/s条件下,挪威复合肥施肥量准确率平均值分别为94.89%和97.82%。理论与试验分析表明,该变量施肥装置调控性能稳定,能够满足水稻侧深变量施肥的作业要求。

水稻高产耕层构建及地力保育技术模式

辽宁省是我国重要的水稻产区,稻田长期重用轻养导致土壤肥力下降、耕层变浅变硬,严重制约了该区域水稻可持续高产能力。以秸秆还田和深耕为核心的水稻高产耕层构建及地力保育技术是黑土地保护与利用的有效技术之一。简述了“高留茬+深翻”和“秸秆粉碎+深旋”两种模式的高产耕层指标、秸秆促腐还田、合理深耕、养分精准调控和适宜密植栽培等主要措施、技术应用效果及存在问题。

秸秆还田与深施氮肥对水稻叶片生理特征、氮素利用及产量的影响

以常规粳稻徐稻10号和新丰7号为材料,设置“深施氮肥+秸秆还田”(DS)、“土壤表层施氮+秸秆还田”(OS)、“深施氮肥+秸秆不还田”(DU)和“土壤表层施氮+秸秆还田”(OU)4个处理,以“不施氮肥+秸秆不还田”作为对照(CK),探索秸秆还田和深施氮肥对水稻剑叶生理特征、籽粒产量及氮肥利用效率的影响。结果表明,与CK相比,DS、OS、DU、OU处理均在一定程度上提高了抽穗期剑叶的净光合速率(Pn)和PSII有效量子效率(Eq),同时提高了水稻干物质累积量和氮素累积量,其中均以DS处理效果最佳;与OU处理相比,抽穗期DS处理的剑叶氮代谢相关酶活性(GS、GOGAT、NR、GDH)显著增加;徐稻10号和新丰7号的籽粒产量DS处理比OU处理分别显著提高46.78%和45.65%。此外,DS处理的氮肥利用率、氮肥农学效率、氮肥偏生产力、氮吸收效率以及氮收获指数在施氮处理中亦最高。以上结果表明,深施氮肥结合秸秆还田是提高河南地区水稻产量、氮肥利用效率的可行措施。

不同深施方式对太湖地区稻田氨挥发和氮肥利用率的影响

本研究以太湖地区稻田为研究对象开展连续两年的田间试验,通过设置不施氮肥(CK)、常规施氮(CN)、减氮表施(RN)、减氮侧深施(RNS)和减氮穴施(RNP)5种施氮处理,探究不同深施方式对稻田氨挥发与氮肥利用率的影响。结果表明,与表施处理(CN和RN)相比,RNS和RNP通过降低田面水NH4+-N浓度和pH分别减少30.95%~41.54%和66.71%~72.23%的氨挥发排放(P<0.05)。相较于RN处理,RNP促进水稻根系生长并增加根区土壤有效氮含量,进而增加水稻产量(6.23%),提高氮肥利用率(50.15%),降低土壤氮盈余(63.92%)(P<0.05)。与CN处理相比,RNS显著降低土壤氮盈余(29.20%)(P<0.05),但水稻吸氮量和氮肥利用率均未显著增加。相较于RNS,RNP进一步降低氨挥发损失(50.84%)和土壤氮盈余(51.07%),提高氮肥利用率(40.40%)(P<0.05)。综上所述,RNP的农学和环境效益最高,但因穴施机械及肥料造粒技术等因素的限制,尚难应用于实际生产;而侧深施肥在我国水稻大规模集约化生产中效益较高且切实可行。

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。