基于田块尺度的小麦产量差及生产限制因素解析

为了解析产量差的产生机制和冬小麦生产的限制因子,提出科学的缩减产量差的途径,本研究通过农户调查的方法对吴桥县不同田块的产量差进行了研究。分析表明:不同田块之间的产量差异明显,高产田块和低产田块之间的产量差距达3 375kg/hm2,与平均产量的差距为1 754kg/hm2,中低产田块具有较大的产量提升空间。通过对调查因素的分析,阐述了田块尺度产量差限制因素的影响作用,土壤肥力、肥料投入、土壤耕作、灌溉和病虫害防治等可控因素是田块产量差的重要限制因素。在冬小麦的生产投入构成中,肥料投入所占比例最大,并且不同收益的农户之间肥料投入呈现出明显的差异,而机械、农药、种子和灌溉等方面的投入差异不大。在投入达到一定水平后,随着投入继续增大,报酬递减,农户的投入与产出间的关系为:当冬小麦投入水平为4 102.5元/hm2,产投比达到最大值4.02。平衡施肥、提高肥料的利用效率是实现少投入高收益的根本途径,提高栽培耕作技术的到位率是缩减田块尺度产量差的重要途径。     

Developing sustainable summer maize production for smallholder farmers in the North China Plain: An agronomic diagnosis method

With an increasing population and changing diet structure, summer maize is increasingly becoming an important energy crop in China. However, traditional farmer practices for maize production are inefficient and unsustainable. To ensure food security and sustainable development of summer maize production in China, an improved, more sustainable farmer management system is needed. Establishing this system requires a comprehensive understanding of the limitations of current farming practice and the ways it could be improved. In our study, 235 plots from three villages in the North China Plain(NCP) were monitored. Maize production on farms was evaluated; our results showed that the maize yield and nitrogen partial factor productivity(PFP_N) were variable on smallholder farms at 6.6~(–1)3.7 t ha~(–1) and 15.4–88.7 kg kg~(–1), respectively.Traditional farming practices also have a large environmental impact(nitrogen surplus: –64.2–323.78 kg ha~(–1)). Key yield components were identified by agronomic diagnosis. Grain yield depend heavily on grain numbers per hectare rather than on the 1 000-grain weight. A set of improved management practices(IP) for maize production was designed by employing a boundary line(BL) approach and tested on farms. Results showed that the IP could increase yield by 18.4% and PFP_N by 31.1%, compared with traditional farmer practices(FP), and reduce the nitrogen(N) surplus by 57.9 kg ha~(–1). However,in terms of IP effect, there was a large heterogeneity among different smallholder farmers' fields, meaning that, precise technologies were needed in different sites especially for N fertilizer management. Our results are valuable for policymakers and smallholder farmers for meeting the objectives of green development in agricultural production.     

施用生物炭对华北平原冬小麦土壤水分和籽粒产量的影响

为探究施用生物炭对华北平原农田土壤水分和冬小麦籽粒产量的影响,于2014—2017年在中国农业大学吴桥实验站设置施用生物炭7 200(BH)、3 600(BM)、1 800(BL)和0kg/hm~2(CK)4个处理。结果表明:与CK处理相比,BH、BM和BL处理3年平均增产分别为1.84%、7.28%和5.03%,并且降低了耗水量,水分利用效率分别提高5.96%～14.86%、9.42%～19.18%和5.96%～13.50%。同时施用生物炭增加了土壤含水量,与CK处理相比,土壤上层0～60cm BM处理增幅最大;中层60～120cm和下层120～200cm均为BL处理增幅最大(P0.05)。综上所述,施用生物炭可以增加土壤含水量和籽粒产量。统计分析表明,当施炭量分别为3 389～3 882和3 500～4 357kg/hm~2,0～60cm土层土壤含水量和籽粒产量均最高,且0～60cm土层土壤含水量与籽粒产量间存在显著的正相关关系(P0.05)。因此,施用生物炭可以增加土壤含水量,降低水分消耗,提高冬小麦籽粒产量和水分利用效率,在本试验条件下以施用3 000～4 500kg/hm~2为宜。     

Yield gap and production constraints of mango (Mangifera indica) cropping systems in Tianyang County,China

Mango is an important cash crop in the tropics and subtropics. Determining the yield gap of mango and production constraints can potentially promote the sustainable development of the mango industry. In this study, boundary line analysis based on survey data from 103 smallholder farmers and a yield gap model were used to determine the yield gap and production constraints in mango plantations in the northern mountain, central valley and southern mountains regions of Tianyang County, Guangxi, China. The results indicated that the yield of mango in three representing regions of Tianyang County,Northern Mountains, Central Valley and Southern Mountains, was 18.3, 17.0 and 15.4 t ha~(–1) yr~(–1), with an explainable yield gap of 10.9, 6.1 and 14.8 t ha~(–1) yr~(–1), respectively. Fertilization management, including fertilizer N, P_2O_5 and K_2O application rates, and planting density were the main limiting factors of mango yield in all three regions. In addition, tree age influenced mango yield in the Northern Mountains(11.1%) and Central Valley(11.7%) regions. Irrigation time influenced mango yield in the Northern Mountains(9.9%) and Southern Mountains(12.2%). Based on a scenario analysis, the predicted yield would increase by up to 50%, and fertilizer N use would be reduced by as much as approximately 20%. An improved understanding of production constraints will aid in the development of management strategy measures to increase mango yield.     

政和县中低产耕地限制因素分析与改良利用对策

对政和县耕地地力调查表明：缺镁型和干旱型的耕地占中低产田总面积的59.54％和54.07％;施肥配比不合理,降雨时空分布不均,水利设施调蓄能力差,分布在坡地等是中低产耕地比例大的主要成因.并据此提出改良利用对策.     

江苏省耕地产量差及生产限制性因子分析

产量差表征粮食增产空间,缩减产量差是提高粮食产量的重要途径,解析产量差限制因子为探索产量差缩减路径、提高粮食产量提供依据。本文基于江苏省2000—2018年地市统计数据,借助边界线分析法定量分析粮食生产限制因子对产量差的贡献率,并解析限制性因子最适值。结果表明：江苏省耕地平均产量差占到最高产量和平均产量的比例分别为23.47%和64.05%,表明粮食产量具有较高的提升空间;苏南、苏中和苏北地区产量差的关键限制性因素分别为复种指数、劳动力和单产;江苏省粮食复种指数为1.6、机械总动力为5.3 kW/hm2、施肥强度为487.64 kg/hm2时粮食产量最高,是粮食生产要素投入最适值,其中施肥量超出施肥警戒线,表明江苏省农业施肥利用效率低下;转化产量差可实现苏南、苏中和苏北粮食增产30.3%、17.73%和21.45%,同时对耕地的需求量减少8.8%、13.38%和9.02%。因此,提出增加耕地复种规模,改善农业生产条件,政府加强对农户施肥指导以及提高机械化水平等缩减江苏省粮食产量差,促进粮食可持续生产和保障粮食安全的政策建议。     

Optimizing agronomic practices for closing rapeseed yield gaps under intensive cropping systems in China

A yield gap analysis for rapeseed(Brassica napus L.) is critical to meeting the oil demand by identifying yield potential and yield constraints. In this study, potential yield(Y_p), attainable yield(Y_(att)), and actual yield(Y_(act)) for winter rapeseed were determined in five different zones of China. A boundary line approach was adopted to calculate Y_p, based on a large-scale field experimental database. A meta-analysis was conducted on the data obtained from 118 published studies to evaluate the effects of agronomic factors on rapeseed yield. The main results indicated that farmers only achieved 37–56% of the yield potential across the zones. The low altitude areas(L-URY) and lower reaches(LRY) of the Yangtze River Basin(YRB), China had high yield levels. The total yield gap was 1 893 kg ha~(–1), due to the agronomic management factors, environmental factors, and socioeconomic factors. The meta-analysis showed that weed control and drainage were the best management practices to improve yields(45.6 and 35.3%, respectively), and other practices improved yields by 17.1–21.6%. Consequently, to narrow the yield gap over the short term, the study could focus on techniques that are easily implemented to farmers.     

小麦-玉米两熟制产量限制因素及其提升技术途径——以山东省龙口市为例

采用半结构访谈方法对山东省龙口市农技推广人员与农业管理人员进行调研,评估当地冬小麦和夏玉米的产量限制因素与产量提升技术途径.结果表明:冬小麦产量的主要限制因素是品种丰产性低、播期过早、播量过大、肥水运筹不合理,5年内可广泛应用于生产的技术措施是测土配方施肥、推广改良品种和玉米秸秆还田.夏玉米产量的主要限制因素是栽培管理粗放、播种质量不高、干旱,5年内可广泛应用于生产的技术措施是推迟套种时间、园地制宜选用良种.从中长期来看,未来5～20年内小麦-玉米两熟制大田生产的产量提升需要栽培管理技术、优良适宜品种、极端气候预防及补救技术措施和提升粮食作物补贴的共同作用.     

Closing the nitrogen use efficiency gap and reducing the environmental impact of wheat-maize cropping on smallholder farms in the Guanzhong Plain,Northwest China

A high crop yield with the minimum possible cost to the environment is generally desirable. However, the complicated relationships among crop production, nitrogen (N) use efficiency and environmental impacts must be clearly assessed. We conducted a series of on-farm N application rate experiments to establish the linkage between crop yield and N₂O emissions in the Guanzhong Plain in Northwest China. We also examined crop yield, partial factor productivity of applied N (PFPN) and reactive N (Nr) losses through a survey of 1 529 and 1 497 smallholder farms that grow wheat and maize, respectively, in the region. The optimum N rates were 175 and 214 kg ha^–1 for winter wheat and summer maize, respectively, thereby achieving the yields of 6 799 and 7 518 kg ha^–1, correspondingly, with low N₂O emissions based on on-farm N rate experiments. Among the smallholder farms, the average N application rates were 215 and 294 kg ha^–1 season^–1, thus producing 6 490 and 6 220 kg ha^–1 of wheat and maize, respectively. The corresponding PFPN values for the two crops were 36.8 and 21.2 kg N kg^–1, and the total N₂O emissions were 1.50 and 3.88 kg ha^–1, respectively. High N balance, large Nr losses and elevated N₂O emissions could be explained by the overdoses of N application and low grain yields under the current farming practice. The crop yields, N application rates, PFPN and total N₂O for wheat and maize were 18 and 24% higher, 42 and 37% less, 75 and 116% higher, and 42 and 47% less, correspondingly, in the high-yield and high-PFPN group than in the average smallholder farms. In conclusion, closing the PFPN gap between the current average and the value for the high-yield and high-PFPN group would increase crop production and reduce Nr losses or the total N₂O emissions for the investigated cropping system in Northwest China.     

Effects of different agricultural treatments on narrowing winter wheat yield gap and nitrogen use efficiency in China

Under the limited cultivated land area and the pursuit of sustainable agricultural development,it is essential for the safety of grain production to study agricultural management approaches on narrowing the winter wheat yield gap and improving nitrogen use efficiency (NUE) in China.In this study,DSSAT-CERES-Wheat Model is used to simulate winter wheat yield under different agricultural treatments,and we analyze yield gaps and NUE with different management scenarios at regional scales and evaluate the suitable approaches for reducing yield gap and increasing NUE.The results show that,the potential of narrowing yield gap ranges 300–900 kg ha~(–1) with soil nutrients increase,400–1 200 kg ha~(–1) with sowing date adjustment and 0–400 kg ha~(–1) with planting density increase as well as 700–2 200 kg ha~(–1) with adding nitrogen fertilizer.Contribution rates of management measures of soil nutrients,sowing date adjusting,planting density,and nitrogen fertilizers are 5–15%,5–15%,0–4%,and 10–20%,respectively.Difference in nitrogen partial productivity ranges 3–10 kg kg~(–1) for soil nutrients,1–10 kg kg~(–1) for sowing date adjusting,1–5 kg kg~(–1) for planting density increase,and–12–0 kg kg~(–1) for adding nitrogen fertilizers,respectively.It indicates that four treatments can narrow yield gap and improve the NUE in varying degrees,but increasing nitrogen fertilizer leads to the decrease of NUE.     

精准农业对华北平原冬小麦温室气体排放和产量的短期影响

本试验以京郊冬小麦田为研究对象,采用大田试验设置4个处理:CTF(常规整地+常规施肥)、PF(精准施肥)、LL(激光平地)、PF+LL(精准施肥+激光平地),采用静态箱-气相色谱法分析了不同农业措施下的土壤温室气体(CO_2、N_2O、CH_4)排放特征。结果表明:和CTF相比,LL冬小麦产量显著提高7.10%;降雨、灌溉后表层土壤含水率显著提高,冬小麦季土壤CH_4吸收量显著增加22%,土壤CO_2、N_2O累计排放量分别显著增加27.20%、8.81%。PF产量与CTF无显著差异;土壤N_2O排放峰出现在追肥后,PF排放峰值显著较CTF低15.41%,精准施肥至收获期间PF土壤N_2O显著减排15.05%,但整个冬小麦生长季PF土壤CO_2、N_2O累计排放量和CH_4累计吸收量与CTF均无显著差异。和CTF相比,PF+LL小麦产量显著提高8.2%,同时PF+LL土壤具备较好的持水性,雨季及灌溉后表层土壤含水率分别显著提高8.81%、7.63%,冬小麦生长季土壤CO_2累计排放量显著增加33.53%,CH_4吸收量显著增加31.5%,N_2O累计排放量无显著差异,但在精准施肥至收获期间土壤N_2O显著减排10.22%。综上,激光平地技术可显著增产但综合增温潜势较强,精准施肥技术对产量无显著影响,但降低了N_2O排放峰值,减少了精准施肥后的N_2O累计排放量,表现出一定的N_2O减排潜力。     

烤烟节水灌溉的研究进展

目的明确云南玉溪烟区烤烟大田生育期适宜滴灌定额。方法2017年通过田间控水试验,以作物蒸散量(ET₀)为基础,设置4个参考需水量水平(50% ET₀、60% ET₀、80% ET₀和100% ET₀)和3个设计湿润比(P,0.4、0.5和0.6),共12个滴灌定额处理,考察不同滴灌定额对烤烟生长发育和水肥利用效率的影响。结果参考需水量水平对烤烟株高、茎干物质量以及氮肥和钾肥利用率有显著影响(P<0.05),对除株高以外的农艺性状、叶和全株干物质量以及灌溉水利用率有极显著影响(P<0.01);设计湿润比对烤烟叶干物质量、根冠比和灌溉水利用率有显著影响(P<0.05),对烤烟主要农艺性状、茎和全株干物质量有极显著影响(P<0.01);两者对烤烟叶片和全株干物质量以及灌溉水利用率的影响存在显著交互效应(P<0.05),对烤烟叶片数和株高的影响存在极显著交互效应(P<0.01)。不同灌溉定额处理中,以80% ET₀-0.5P处理烤烟成熟期生物量和农艺性状表现较优,氮、磷和钾肥及灌溉水利用率相对较高;与其他处理相比,其成熟期烤烟叶片和全株干物质量分别增加了14.6%~97.5%和4.3%~72.8%,氮肥和磷肥利用率分别提高了9.4%~84.2%和11.3%~178.1%。结论本试验条件下,该区域较为适宜的烤烟大田生育期滴灌灌溉定额为200 mm。     

The water-saving potential of using micro-sprinkling irrigation for winter wheat production on the North China Plain

The shortage of groundwater resources is a considerable challenge for winter wheat production on the North China Plain. Water-saving technologies and procedures are thus urgently required. To determine the water-saving potential of using micro-sprinkling irrigation(MSI) for winter wheat production, field experiments were conducted from 2012 to 2015. Compared to traditional flooding irrigation(TFI), micro-sprinkling thrice with 90 mm water(MSI1) and micro-sprinkling four times with 120 mm water(MSI2) increased the water use efficiency by 22.5 and 16.2%, respectively, while reducing evapotranspiration by 17.6 and 10.8%. Regardless of the rainfall pattern, MSI(i.e., MSI1 or MSI2) either stabilized or significantly increased the grain yield, while reducing irrigation water volumes by 20–40%, compared to TFI. Applying the same volumes of irrigation water, MSI(i.e., MSI3, micro-sprinkling five times with 150 mm water) increased the grain yield and water use efficiency of winter wheat by 4.6 and 11.7%, respectively, compared to TFI. Because MSI could supply irrigation water more frequently in smaller amounts each time, it reduced soil layer compaction, and may have also resulted in a soil water deficit that promoted the spread of roots into the deep soil layer, which is beneficial to photosynthetic production in the critical period. In conclusion, MSI1 or MSI2 either stabilized or significantly increased grain yield while reducing irrigation water volumes by 20–40% compared to TFI, and should provide water-saving technological support in winter wheat production for smallholders on the North China Plain.     

Improved simulation of winter wheat yield in North China Plain by using PRYM-Wheat integrated dry matter distribution coefficient

The accurate simulation of regional-scale winter wheat yield is important for national food security and the balance of grain supply and demand in China. Presently, most remote sensing process models use the “biomass×harvest index(HI)” method to simulate regional-scale winter wheat yield. However, spatiotemporal differences in HI contribute to inaccuracies in yield simulation at the regional scale. Time-series dry matter partition coefficients(Fr) can dynamically reflect the dry matter partition...     

Grain yield and water use of winter wheat as affected by water and sulfur supply in the North China Plain

Water shortage has threatened sustainable development of agriculture globally as well as in the North China Plain(NCP).Irrigation,as the most effective way to increase food production in dry land,may not be readily available in the situation of drought.One of the alternatives is to supply plants with enough nutrients so that they can be more sustainable to the water stress.The objective of this study was to explore effects of irrigation and sulphur(S)application on water consumption,dry matter accumulation(DMA),and grain yield of winter wheat in NCP.Three irrigation regimes including no irrigation(rainfed,I_0)during the whole growth period,once irrigation only at jointing stage(90 mm,I_1),and twice respective irrigation at jointing and anthesis stages(90 mm plus 90 mm,I_2),and two levels of S application including 0(S_0)and 60 kg ha~(–1)(S_(60))were designed in the field experiment in NCP.Results showed that increasing irrigation times significantly increased mean grain yield of wheat by 12.5–23.7%and nitrogen partial factor productivity(NPFP)by 21.2–45.0%in two wheat seasons,but markedly decreased crop water use efficiency(YWUE).Furthermore,S supply 60 kg ha~(–1) significantly increased mean grain yield,YWUE,IWUE and NPFP by 5.6,6.1,23.2,and 5.6%(across two wheat seasons),respectively.However,we also found that role of soil moisture prior to S application was one of important greater factors on improving the absorption and utilization of storage water and nutrients of soil.Thus,water supply is still the most important factor to restrict the growth of wheat in the present case of NCP,supplying 60 kg ha~(–1) S with once irrigation 90 mm at the jointing stage is a relatively appropriate recommended combination to improve grain yield and WUE of wheat when saving water resources is be considered in irrigated wheat farmlands of NCP.     

Yield and water use responses of winter wheat to irrigation and nitrogen application in the North China Plain

With increasing water shortage resources and extravagant nitrogen application, there is an urgent need to optimize irrigation regimes and nitrogen management for winter wheat(Triticum aestivum L.) in the North China Plain(NCP). A 4-year field experiment was conducted to evaluate the effect of three irrigation levels(W1, irrigation once at jointing stage; W2, irrigation once at jointing and once at heading stage; W3, irrigation once at jointing, once at heading, and once at filling stage; 60 mm each irrigation) and four N fertilizer rates(N0, 0; N1, 100 kg N ha~(-1); N2, 200 kg N ha~(-1); N3, 300 kg N ha~(-1)) on wheat yield, water use efficiency, fertilizer agronomic efficiency, and economic benefits. The results showed that wheat yield under W2 condition was similar to that under W3, and greater than that under W1 at the same nitrogen level. Yield with the N1 treatment was higher than that with the N0 treatment, but not significantly different from that obtained with the N2 and N3 treatments. The W2 N1 treatment resulted in the highest water use and fertilizer agronomic efficiencies. Compared with local traditional practice(W3 N3), the net income and output-input ratio of W2 N1 were greater by 12.3 and 19.5%, respectively. These findings suggest that two irrigation events of 60 mm each coupled with application of 100 kg N ha~(–1) is sufficient to provide a high wheat yield during drought growing seasons in the NCP.     

Growth and nitrogen productivity of drip-irrigated winter wheat under different nitrogen fertigation strategies in the North China Plain

Excessive application of nitrogen (N) fertilizer is the main cause of N loss and poor use efficiency in winter wheat (Triticum aestivum L.) production in the North China Plain (NCP).  Drip fertigation is considered to be an effective method for improving N use efficiency and reducing losses, while the performance of drip fertigation in winter wheat is limited by poor N scheduling.  A two-year field experiment was conducted to evaluate the growth, development and yield of drip-fertigated winter wheat under different split urea (46% N, 240 kg ha^–1) applications.  The six treatments consisted of five fertigation N application scheduling programs and one slow-release fertilizer (SRF) application.  The five N scheduling treatments were N0–100 (0% at sowing and 100% at jointing/booting), N25–75 (25% at sowing and 75% at jointing and booting), N50–50 (50% at sowing and 50% at jointing/booting), N75–25 (75% at sowing and 25 at jointing/booting), and N100–0 (100% at sowing and 0% at jointing/booting).  The SRF (43% N, 240 kg ha^–1) was only used as fertilizer at sowing.  Split N application significantly (P<0.05) affected wheat grain yield, yield components, aboveground biomass (ABM), water use efficiency (WUE) and nitrogen partial factor productivity (NPFP).  The N50–50 and SRF treatments respectively had the highest yield (8.84 and 8.85 t ha^–1), ABM (20.67 and 20.83 t ha^–1), WUE (2.28 and 2.17 kg m^–3) and NPFP (36.82 and 36.88 kg kg^–1).  This work provided substantial evidence that urea-N applied in equal splits between basal and topdressing doses compete economically with the highly expensive SRF for fertilization of winter wheat crops.  Although the single-dose SRF could reduce labor costs involved with the traditional method of manual spreading, the drip fertigation system used in this study with the N50–50 treatment provides an option for farmers to maintain wheat production in the NCP.     

Impacts of climate change on drought risk of winter wheat in the North China Plain

Drought is a major natural disaster causing crop yield losses, while its occurrence mechanism and spatiotemporal variations in a changing climate are still not clear. Based on a long-term climatic dataset(during 1958–2015) from weather stations in the North China Plain(NCP), the influencing mechanism of various climatic factors on drought risk of winter wheat was quantified by using sensitivity analysis, Mann-Kendall trend test and slope estimation. The results indicated that climatic factors have changed considerably over the past six decades in the growth season of winter wheat. As a result, winter wheat suffered from severe droughts(with 350 mm of water deficit during its growth season), particularly at the jointing–heading and heading–mature stages, which were critical to crop yield formation. There were large spatial and temporal variations in drought risk and climatic change factors at different growth stages of winter wheat. Despite precipitation playing a vital role in determining the spatiotemporal patterns of drought risk, high temperature and low humidity along with other climatic factors at key growth stages of winter wheat aggravated drought risk. Particularly, temperature at nearly 90% weather stations showed a notablely upward trend, which exacerbated water deficit and drought risk of winter wheat. Given the complexity and high uncertainty of climate change, these findings provide important information for adapting crop production to future climate change and accompanied droughts while ensuring food security and agricultural sustainability.     

基于农户尺度的闻喜县冬小麦产量差及生产限制因素分析

[目的]缩减不同农户间冬小麦产量的差距对于提升区域粮食产能有重要意义,农户采用田间管理措施的差异是造成农户间产量差的重要因素之一。[方法]本研究以山西省冬小麦种植大县闻喜县为例,基于调查问卷分析法评价了不同田间管理措施下农户尺度冬小麦产量及其构成因素的差异。[结果]闻喜县农户尺度冬小麦实际产量2.35～10.56 t·hm-2,其中89.2%的农户产量高于山西省、运城市及闻喜县平均产量。冬小麦生产中75.3%的农户进行了灌溉,其中灌溉2次和3次条件下的农户产量较灌溉1次和无灌溉显著提高了17.5%～52.0%,灌溉3次提高了穗粒数和千粒重,灌溉2次提高了穗数。33.3%的农户采用叶面施肥,其中喷施1次条件下可通过增加冬小麦的千粒重而实现增产。72.0%的农户播量在121～240 kg·hm-2,该播量段较60～120 kg·hm-2播量段提高了产量及其构成因素。播种期对不同农户冬小麦实际产量及其构成因素均无显著影响。随着农药喷施次数的增加,冬小麦穗数增加,实际产量提升,其中76.3%的农户喷施1～2次农药,较不喷农药显著增加了穗粒数,提升了产量。[结论]在当地目前的冬小麦生产技术水平条件下,在拔节至灌浆期进行1～2次灌溉、播种量181～240 kg·hm-2、实施2～3次病虫草害防治及生长中后期进行1次叶面肥喷施等措施可能是缩小农户产量差异的有效措施。     

种植密度对两种穗型冬小麦旗叶氮代谢酶活性及籽粒蛋白质含量的影响

目的分析晚播对弱筋小麦氮素积累与利用的影响。方法以弱筋小麦品种扬麦13和宁麦13为材料,在不同氮素水平下(N210：210 kg/hm²、N270：270 kg/hm²)设置适播与晚播处理,分析弱筋小麦氮素积累与利用情况。结果弱筋小麦开花期植株氮素积累量主要来源于土壤氮(70.48%~85.51%);成熟期籽粒氮素积累量主要来源于土壤氮(74.35%~86.86%);成熟期营养器官氮素积累主要来源于肥料氮(52.88%~82.12%)。与适期播种相比,晚播显著增加了小麦成熟期单株氮素积累量、开花期来源于土壤氮的积累量、成熟期营养器官和籽粒来源于土壤氮及肥料氮的积累量。弱筋小麦花前营养器官积累氮素向籽粒的转运率为55.52%~79.78%,氮素积累转移的贡献率为38.91%~77.99%。适期播种处理下,花前营养器官氮素积累转运量、转运率与贡献率分别为23.47 mg/株、75.23%和71.46%,而晚播显著降低花前营养器官氮素积累转运量、转运率与贡献率(分别为19.87 mg/株、59.74%和50.31%)。各处理小麦氮肥生产效率为25.25~44.27 kg/kg,氮素利用效率为15.75%~41.43%,氮素收获指数为0.730~0.844。同一因素下不同水平比较表明：晚播显著降低籽粒产量、氮肥生产效率、氮素利用效率及氮素收获指数,但播期对籽粒蛋白质含量无显著影响。在相同品种和氮水平处理下,晚播较适期播种籽粒产量降低。结论弱筋小麦晚播不利于籽粒产量的提高和氮素利用效率的提高,因此为获得较高产量水平与氮素利用效率,应尽量保证弱筋小麦适宜播种期。