Timing and level of nitrogen supply affect nitrogen distribution and recovery in two contrasting oat genotypes

Human diets containing oat (Avena sativa L.) grain offer health benefits resulting in an emerging interest in oat improvement. Information on nitrogen (N) uptake, distribution, and use efficiency (NUE) in oat is limited. A greenhouse study using a ¹⁵N‐labeling technique was conducted to determine the responses of two contrasting oat genotypes to timing and level of N deficiency. Hulled oat cv. Prescott and hulless cv. AC Gehl were grown in soil‐mix pot culture with five N treatments applied through modified Hoagland solutions. Differences in ¹⁵N accumulation, ¹⁵N distribution, plant N originating from the labeled source, and NUE between the contrasting cultivars, were examined for each N strategy. Level of N deficiency and timing of N supply of ¹⁵NH₄¹⁵NO₃ greatly affected ¹⁵N distribution, the origins of plant N, and the amount of ¹⁵N recovered in the plant. When N was supplied from seedling emergence to maturity (T₁), AC Gehl accumulated 61% more ¹⁵N in the shoots, but 46% less ¹⁵N in the grain than Prescott (0.43 vs. 0.80 mg plant^–1), indicating that AC Gehl was less effective in producing grain yield than Prescott as AC Gehl produced greater total dry matter (DM). Withholding N supply until flag‐leaf stage (FL) increased ¹⁵N in the grain of both cultivars by 29.6%, resulting in the highest NUE. In most cases, there were larger portions of plant N derived from the labeled source for AC Gehl than for Prescott. Our results suggest that greater NUE in the newly released AC Gehl was associated with N accumulation in the vegetative tissues. It is concluded that genotype improvement of hulless oat should be focused on enhancing N‐translocation efficiency.     

氮素形态对强筋和中筋小麦产量和品质的影响

[目的]研究不同氮素形态对强筋和中筋小麦植株生长、籽粒蛋白质含量及产量的影响,为选择适宜氮肥种类、提高氮素利用率提供科学依据.[方法]选用强筋小麦'藁优2018'和中筋小麦'济麦22'在河北邢台进行田间试验.在相同施氮量下,设置5个氮源处理:不施氮肥(CK)、酰胺态氮肥(Urea)、铵态氮肥(NH4+-N)、硝态氮肥(...     

Effects of NPK source on the dry matter partitioning in cool season C3-cereals (wheat,rye, barley,and oats) at various growth stages

Dry matter (DM) partitioning into root, leaf, stem, shoot dry weight plant^?1 response in four cool season C₃-cereals viz. wheat (Triticum aestivum L.), rye (Secale cereale L.), barley (Hordeum vulgare L.) and oats (Avena sativa L.) was investigated at 30, 60 and 90 days after emergence (DAE) under eight nitrogen, phosphorus and potassium (NPK) sources: S₁ = 20-20-20, S₂ = 20-27-5, S₃ = 7-22-8, S₄ = 10-10-10-20S, S₅ = 11-15-11, S₆ = 31-11-11, S₇ = 24-8-16, and S₈ = 19-6-12 in pot experiment at Dryland Agriculture Institute, West Texas A&;M University, Canyon, Texas, USA during winter 2009-10. A considerable variation in DM partitioning into various plant parts was observed in the four crop species at different growth stages and NPK source. At 30 DAE, 27% of the total DM per plant (TDMPP) was partitioned into roots and 73% into shoots (19% stems + 54% leaf). Only16 % of the TDMPP was partitioned into roots and 84% into shoots (18 % stem + 66 % leaf) at 60 DAE. At 90 DAE, 29% of TDMPP was partitioned into roots and 71 % into shoots (33 % stems + 38 % leaf) at 90 DAE. Percent DM partitioning into stems ranked first (33%) at 90 DAE > at 30 DAE (19%) > at 60 DAE (18 %). With advancement in crops age, DM partitioning into various crop parts increased. The root DM plant^?1 (RDMPP) increased from 11.5–722 mg plant^?1; stem DM plant^?1 (STDMPP) from 8.3–889.0 mg plant^?1; leaf DM plant^?1 (LDMPP) from 23.1–1031.0 mg plant^?1; shoot DM plant^?1 (SHDMPP) from 31.3–1921 mg plant^?1, and TDMPP increased from 42.9–2693.0 mg plant^?1 at 30 and 90 DAE, respectively. Because of the higher N contents in S₇ (24:8:16) and S₆ (31:11:11) reduced the DM partitioning into various plants parts as well as TDMPP at all three growth stages. The adverse effects of S₆ and S₇ on DM partitioning was more on oats > rye > wheat > barley. The S₄ with 10:10:10 (NPK) and :20S was not toxic at 30 DAE, but at 60 and 90 DAE it became toxic that adversely affected the DM partitioning as well as TDMPP probably may be due its high sulfur (20%) content which lacking in other NPK sources. The DM partitioning to various parts of barley and wheat was more than oats and rye at different growth stages (barley > wheat > rye > oats). Since the DM portioning values were determined on the average of five plants in pot experiment under organic soil at field capacity; in case of field experiments more research is needed on various crop species/varieties under different environmental conditions particularly under moisture stress condition.     

Ermittlung von Kennwerten optimaler Magnesium-Versorgung für Hafer,Sommerweizen und Mais

Determination of plant analysis criteria characterizing the magnesium nutrition of oats, spring wheat and maize Cereal plants from pot trials were analyzed for criteria of optimal Mg nutrition. The critical Mg concentration in dry matter of aerial parts from oats and spring wheat at the beginning of the shooting stage was found to be 1.8 and 1.3 per mille Mg respectively. The critical Mg concentration with maize is about 2,2 per mille in dry matter of yount leaves at tasseling stage. Because the Mg content of oats (based on dry matter) decreases significantly during the shooting stage, it seems advisable to have additional data (Mg content of green matter, Mg/N ratio, Mg/Ca ratio) which are less influenced by plant age. The Mg/Ca ratio appears to be well suited for evaluating the nutritional status of cereals. Minimum critical Mg/Ca ratios (based on per mille contents) are 0,23 for spring wheat, 0.3 for oats and 0.4 for maize.     

Dry matter and nitrogen accumulations in determinate soybean grown on low‐nitrogen soils of the southeastern United States

Abstract

Reliable assessments of erosion potential, N fertilization need, and nitrogen (N) non‐point pollution potential for soybean [Glycine max (L.) Merr.] cropping systems require accurate estimates of soybean dry matter and N accumulations. The objective of this field study was to determine dry matter and N accumulation in soybean during the growing season and at harvest in samples large enough to reduce sample variation and increase the confidence in measured values. A split‐plot design was used with cultivar (Braxton, Coker 338, and Davis) as the main plot treatment and sampling date as the split‐plot treatment. Each split‐plot contained eight rows 4.6 m in length on 0.75 m spacing. The seed were sown in a Norfolk loamy sand (fine‐loamy, siliceous, thermic, Typic Paleudult) on May 18 at the rate of 33 seeds/m. Water was applied by use of an overhead irrigation gun. Plant samples were collected from 20 m² of the six center rows on 89, 115, and 138 days after planting as well as at seed harvest. Fallen plant material (crop litter) was collected from each plot at each sampling date. Itact plant samples, crop litter, and soil samples were analyzed for total Kjeldahl N. The mean seed yield was 2.01 Mg/ha; the mean maximum dry matter accumulation for intact shoots plus crop litter was 10.2 Mg/ha, and the coefficients of variation were <10%. The actual harvest index (seed yield/total dry matter accumulation) ranged from 0.19 to 0.28, and the mean maximum N accumulation was 293 kg/ha. These accumulations are greater than those reported for indeterminate soybean grown on high‐N soils in the midwestern United States, and they clearly show that determinate soybean grown in the southeastern United States accumulate substantial amounts of dry matter and N.     

Availability of soil and fertilizer nitrogen to wheat (Triticum aestivum L.) following rice-straw amendment

Summary A pot experiment was conducted to study the N availability to wheat and the loss of ¹⁵N-labelled fertilizer N as affected by the rate of rice-straw applied. The availability of soil N was also studied. The straw was incorporated in the soil 2 or 4 weeks before a sowing of wheat and allowed to decompose at a moisture content of 60% or 200% of the water-holding capacity. The wheat plants were harvested at maturity and the roots, straw, and grains were analysed for total N and ¹⁵N. The soil was analysed for total N and ¹⁵N after the harvest to determine the recovery of fertilizer N in the soil-plant system and assess its loss. The dry matter and N yields of wheat were significantly retarded in the soil amended with rice straw. The availability of soil N to wheat was significantly reduced due to the straw application, particularly at high moisture levels during pre-incubation, and was assumed to cause a reduction in the dry matter and N yields of wheat. A significant correlation (r=0.89) was observed between the uptake of soil N and the dry matter yield of wheat with different treatments. In unamended soil 31.44% of the fertilizer N was taken up by the wheat plants while 41.08% of fertilizer N was lost. The plant recovery of fertilizer N from the amended soil averaged 30.78% and the losses averaged 45.55%     

施氮量对冬小麦氮素吸收、转运及产量的影响

2004至2005年在田间条件下,研究了施氮量0、105、2103、15.kg/hm2对冬小麦氮素吸收、累积、转运、产量及氮肥利用率的影响。结果表明,施用氮肥可显著提高冬小麦的子粒、秸秆产量及成熟期地上部总吸氮量,但过量施用氮肥对子粒和秸秆增产不显著;各施氮处理的氮肥利用率在34.2%～38.3%之间,随施氮量增加而略有降低。植株中氮素含量随生育期的延长而降低,氮素累积量总体呈增加趋势。施氮量对冬小麦氮素吸收有显著影响,同一生育时期,氮素含量和累积量都随着施氮量增加而提高。施氮可显著地促进氮素在子粒中累积,其中69%～87%的氮素是靠营养体的转运而来的。施氮量影响氮素的转运效率,随施氮量增加,转运效率降低。本试验条件下,冬小麦的合理施氮量应控制在105～210.kg/hm2之间。     

Growth,yield and nutrient uptake of taro grown under upland conditions

There is a scarcity of basic information on dry matter accumulation by various plant organs, nutrient uptake, and yield of taro [Colocasia esculenta (L.) Schott] grown under upland conditions. These data are essential for the development of technological packages, growth simulation models, and decision support systems designed to promote agrotechnology transfer of the crop in the tropics. Two taro cultivars were planted and harvested for biomass about every six weeks during the growing season. At each harvest, plants were separated into various plant parts and their dry matter and nutrient content were determined. There were no significant differences (P<0.05) in total and edible dry matter content between cultivars. However, cultivar ‘Lila’ absorbed significantly smaller amounts of nitrogen (N), phosphorus (P), potassium (K), calcium (Ca), and zinc (Zn) than cultivar ‘Blanca’, suggesting that it had a higher nutrient‐use efficiency. Fresh corm yields were not significantly different and averaged 20,221 kg/ha for both cultivars.     

Grain yield,growth response,and water use efficiency of direct wet-seeded rice as affected by nitrogen rates under alternate wetting and drying irrigation system

ABSTRACT

The present investigation aimed to determine the effectiveness of different nitrogen (N) rates on grain yield, growth, and water use efficiencies of direct wet-seeded rice and to create a relationship of N rates with growth parameters and dry matter production at different stages. The experiments compared six rates of nitrogen (0, 40,80,120,160, and 200 kg ha^–1N) replicated thrice in randomized complete block design in two conjunctive years of 2009–2010 and 2010–2011 at Bangladesh Rice Research Institute farm, Gazipur.The highest grain yield of 7.85 and 7.22 t ha^?1 was observed in N₂₀₀ treatment in 2009–2010 and 2010–2011, respectively. The relationship (R²) of total dry matter with leaf area index , leaf area duration, and crop growth rate indicated strong association during booting stage to achieved maximum dry matter during harvest. Water use efficiency varied 87–91% in different N levels.     

Tillering,nutrient accumulation,and yield of winter wheat as influenced by nitrogen form 1

When grown with mixtures of nitrate‐nitrogen (NO₃‐N) and ammonium‐nitrogen (NH₄‐N) (mixed N) spring wheat (Triticum aestivum L.) plants develop higher order tillers and produce more grain than when grown with only NO₃. Because similar work is lacking for winter wheat, the objective of this study was to examine the effect of N form on tillering, nutrient acquisition, partitioning, and yield of winter wheat. Plants of three cultivars were grown to maturity hydroponically with nutrient solutions containing N as either all NO₃, all NH₄, or an equal mixture of both forms. At maturity, plants were harvested; separated into shoots, roots, and grain; and each part analyzed for dry matter and chemical composition. While the three cultivars varied in all parameters, mixed N plants always produced more tillers (by a range of 16 to 35%), accumulated more N (28 to 61%), phosphorus (P) (22 to 80%), and potassium (K) (11 to 89%) and produced more grain (33 to 60%) than those grown with either form alone. Although mixed N‐induced yield increases were mainly the result of an increase in grain bearing tillers, there was cultivar specific variation in individual yield components (i.e., tiller number, kernels per tiller, and kernel weight) which responded to N form. The presence of NH₄ (either alone or in the mixed N treatment), increased the concentration of reduced N in the shoots, roots, and grain of all cultivars. The effect of NH₄ in either treatment on the concentrations of P and K was variable and depended on the cultivar and plant part. In most cases, partitioning of dry matter, P, and K to the root decreased when NH₄ was present, while partitioning of N was relatively unaffected. Changes in partitioning between the shoot and grain were affected by N treatment, but varied according to cultivar. Based on these data, the changes in partitioning induced by NH₄ and the additional macronutrient accumulation with mixed N are at least partially responsible for mixed‐N‐induced increases in tillering and yield of winter wheat.     

Growth,Chlorophyll, and Cation Concentration of Tetraploid Wheat on a Solution High in Sodium Chloride Salt: Hulled Versus Free-Threshing Genotypes

Based on the literature, under-utilized hulled wheats could be tolerant to some harsh environmental conditions. The effect of salt stress on chlorophyll content, leaf area, dry weight, and ion concentrations in eight genotypes of tetraploid wheat (Triticum turgidum) using a three-replicate completely random design indoor experiment was studied. These genotypes included six hulled wheat (HW), T. turgidum subspp. Dicoccum, and two free-threshing wheat (FTW), T. turgidum subspp. durum. Salt stress was induced by adding sodium chloride (NaCl) to a hydroponic medium to 40, 80, and 120 mM, in addition to control. Salinity reduced leaf content of chlorophyll a (chl-a) at 120 mM but had not significant effect on chlorophyll b (chl-b) content. Salt stress decreased plant leaf area by nearly 63%. Plant top dry weight declined by 52% with increasing salinity to 120 mM level. Plant top calcium (Ca²⁺) content was not affected, whereas plant top sodium (Na⁺) concentration increased and potassium (K⁺) and magnesium (Mg⁺) concentration decreased with increasing salinity, averaged over genotypes. No significant interaction of genotype × salinity was detected for traits studied in this experiment. When contrasted as two groups of genotypes, i.e., HW vs. FTW, the former group suffered more severe decreases in terms of chl-a, chl-b, leaf area, dry weight, and Mg²⁺ concentration and a more pronounced increase in Na⁺ compared to the FTW. Overall, no evidence of salt tolerance was found for hulled tetraploid wheats of central Iran.     

Vegetative responses of silage cats fertilized in the growth chamber with various levels of N and K

Oats (Avena sativa L.) are often harvested for silage in the Great Lakes states. The objective of this research was to obtain additional information on the response of oats to N and K fertilization. ‘Froker’ spring oats were grown from seed under 27 C day/21 C night temperatures in a growth chamber. The soil was a 4:1 mixture of Dodge silt loam soil (Typic Argiudoll) and sand that contained low levels of N and K. The potted plants were fertilized with 0, 50, 100, and 200 kg/ha of N as NH₄NO₃ in all combinations with 0, 200, and 400 kg/ha of K as KC1. Plants were harvested at early inflorescence emergence (43 days after seeding). Fertilization with N significantly increased the dry matter yields (g/pot) of the herbage and total plant, the number of axillary tillers/pot, and herbage N percentage. Root yields were increased only with the first increment of N. Nitrogen fertilization had no significant effect on height of the primary shoots and herbage K percentage. The first increment of K (200 kg K/ha) significantly increased herbage and total plant dry matter yields, while the second increment (400 kg K/ha) gave no further yield increases. However, number of axillary tillers/pot and herbage K percentage were increased significantly with each higher K rate. Potassium fertilization had no significant effect on root yield, primary shoot height, and herbage N percentage. It was concluded that the vegetative growth of oats is very responsive to N fertilization to the highest rate applied (200 kg N/ha), but responds only to the first increment of K (200 kg K/ha).     

播期与施氮量对花生干物质、产量及氮素吸收利用的影响

[目的]在大田条件下,研究播期与施氮量对不同类型花生产量、干物质积累、氮素吸收及利用的影响,为花生高产和养分资源高效利用提供技术支撑.[方法]选择普通型大花生品种'花育22号'和高油酸花生品种'冀花16号'为材料,设3个施氮水平:0、120、240?kg/hm2?(分别表示为N0、N120、N240);4个播期:4月3...     

施钾对青引1号燕麦草产量及根系的影响

在缺钾地区，开展了不同施钾对青引1号燕麦（Avena sativa cv. Qingyin No.1）干物质产量和根系的影响，找出最佳施钾量，为青海省燕麦种子生产提供依据。结果表明，在施N 54.75 kg/hm2和施P2O5 51.75 kg/hm2的基础上，施K2O 40 kg/hm2，青引1号燕麦开花期收获时可获得最高的干物质产量和蛋白产量，分别为29575.0和2099.8 kg/hm2，二者均符合Y=a+bK+cK2函数变化。施K2O 40 kg/hm2，青引1号燕麦株高、总分蘖数、根长和根数最大，分别为184.5 cm、3.22个/株、15.90 cm和26.17 条/株； 施K2O 20 kg/hm2时，植株茎粗和根量达最大，分别为0.585 cm和0.540 g/株。各产量性状、地下生物量以及饲草和蛋白产量间均存在显著或极显著正相关关系。     

32P Isotope to Determine the Efficiency of Mycorrhizal Wheat Symbiosis Subjected to Saline Water

Phosphorus (P) behavior and its efficiency in mycorrhizal plants are of great importance. The objective was to evaluate the behavior of soil labeled P absorbed by different mycorrhizal wheat genotypes subjected to saline water. Three wheat genotypes including cultivar Kavir, the local cultivar Roshan, and the mutated line Tabasi T-65-7-1 were inoculated with different species of arbuscular mycorrhiza (AM) including Glomus etunicatum, G. mosseae, and G. intraradices. Plants were irrigated using saline water (electrical conductivity of 13.87 dS m^?1). The experiment was a factorial with 12 treatments and three replications under greenhouse conditions. Wheat genotypes and AM species significantly affected plant dry weight, specific activity, and total plant activity (P?=?0.01). A maximum of 1.49-fold increase in specific activity or P uptake per gram of plant dry matter and 3.53-fold increase in plant activity or plant total P uptake resulted by G. etunicatum as compared with control.     

超高产夏玉米干物质与氮、磷、钾养分积累与分配特点

探讨超高产夏玉米品种整株干物质与氮、磷、钾养分积累分配特点,为制定高产栽培管理措施提供依据.本文在大田条件下,以登海661(DH661)和郑单958(ZD958)为试验材料,比较研究了超高产夏玉米干物质与氮、磷、钾养分积累分配特点.结果表明,超高产夏玉米DH661在成熟期内整株干物质及氮、磷、钾积累量分别为33475.53 kg/hm2、369.76 kg/hm2、117.85 kg/hm2、285.78 kg/hm2,均显著高于ZD958,较ZD958分别高15.82％、23.72％、32.17％、21.89％.超高产夏玉米DH661的干物质和氮、磷、钾养分在叶片和茎秆中的分配比例均低于ZD958,而籽粒和根系中的分配比例高于ZD958,因而具有较高的养分收获指数与偏生产力.整个生育期内,DH661各器官的养分吸收速率均显著高于ZD958,具有较高的养分吸收效率;茎、叶及根系的氮、磷、钾养分吸收速率在灌浆期前保持较高水平,之后下降较快,而籽粒的氮、磷、钾养分吸收速率于灌浆期后增加较快.吐丝期后,DH661仍能吸收积累较多的养分,因此吐丝后适当追肥对于超高产夏玉米灌浆期养分充足供应至关重要.     

Forage grass response to harvest interval and reclaimed water

Accumulation of dry matter and plant nutrients by perennial grass over the growing season is dependent upon harvest interval and availability of water and applied nutrients. Mathematical models are frequently incorporated in the analysis, design, and operation of systems for land application of reclaimed water (municipal or agricultural). The objective of the present work was to measure response of warm‐season Coastal bermudagrass [Cynodon dactylon (L.)] to irrigation with reclaimed municipal wastewater and to evaluate parameters for a simplified model. Grass was harvested at intervals of 2, 4, and 6 wk. Measurements included yields (dry matter and digestible organic matter) and plant nutrient uptake (N, P, and K). The probability model described time trends rather well. The linear model parameter A showed linear dependence on harvest interval At over the range studied, in agreement with results from the literature. Maximum values for a harvest interval of 6 wk were 16.5 Mg ha^‐1 (dry matter), 8.0 Mg ha^‐1 (digestible organic matter), 350 kg N ha^‐1,57 kg P ha^‐1, and 272 kg K ha^‐1.     

秋闲期秸秆覆盖与氮肥减施对旱地冬小麦干物质积累、结实特性和产量的影响

[目的]研究秋闲期秸秆覆盖对旱地小麦播前土壤墒情和小麦生产特性的影响以及减少氮肥用量的可行性,为四川旱地小麦高产高效管理提供理论依据.[方法]于2016―2018年在四川省仁寿县四川农业大学试验基地开展冬小麦–夏玉米轮作田间定位试验,供试作物为冬小麦.试验采用裂区设计,主区为夏玉米秸秆粉碎覆盖(SM)和不覆盖(NM);...     

Losses of 15N-nitrogen by plant–soil system after herbicide application on black oat

Recent studies have demonstrated that the use of glyphosate or glufosinate-ammonium herbicides for some cover crop desiccation in conservationist systems could favor nitrogen (N) losses from the soil–plant system. In this context, the objective of this study was to evaluate the losses of N by the plant–soil system after the desiccation of black oat (Avena strigosa Schreb.) with the application of herbicides glyphosate, glufosinate-ammonium, or paraquat. Two greenhouse experiments were implemented using black oat plants fertilized with labeled (¹⁵N) ammonium nitrogen, and the N loss of the plant–soil system was quantified. The desiccation of black oat with glyphosate caused a reduction in root dry mass by approximately 60% in both experiments. The glyphosate and glufosinate-ammonium reduced the amount of N present in the aboveground portion; however, the paraquat herbicide did not modify it. None of the herbicides applied affected N losses in the black oat plant–soil system. However, 5–15% of the N applied as fertilizer was lost up to harvest. The results suggest that black oat can be used as a cover crop in direct sowing in order to avoid nitrogen losses in the soil–plant system.     

灌溉量和施氮量对油用亚麻茎秆抗倒性能及产量的影响

为明确灌水和施氮对油用亚麻(Linum usitatissimum L.)抗倒伏能力和产量的影响,以‘陇亚杂1号’为材料,于2012—2013年以灌溉量为主处理(W1:2 700 m3·hm-2;W2:3 300 m3·hm-2),施氮量为副处理[纯氮量分别为N0:0 kg·hm-2(CK);N1:37.5 kg·hm-2(低氮);N2:112.5 kg·hm-2(中氮);N3:225 kg·hm-2(高氮)],研究灌溉量和施氮量对与油用亚麻抗倒性能相关的形态学特性、茎秆强度、抗倒伏指数及茎秆化学组分含量、产量构成因子及产量的影响。结果表明,随灌溉量的增加,茎秆强度和抗倒伏指数下降,株高增加,重心上移,茎粗、茎壁厚度降低,地上部干重增加,根干重减少,根冠比下降,同时茎秆中纤维素、木质素、可溶性糖和淀粉的含量下降;随施氮量的增加,茎秆强度和抗倒伏指数先升高后降低,株高和重心高度增加,茎粗、茎壁厚度、根干重和根冠比先增后减,地上部干重增加,茎秆中各化学组分含量及产量也先增加后降低。进一步分析发现抗倒伏指数与茎秆强度、茎粗、茎壁厚度、根干重、根冠比、纤维素含量、木质素含量、可溶性糖含量及淀粉含量均呈正相关关系,与株高、重心高度、地上部干重呈负相关关系。低灌水处理(W1)的茎秆强度、抗倒伏指数和产量分别比高灌水处理(W2)高30.55%、41.06%和0.53%,过多灌水不利于油用亚麻茎秆抗倒伏性能和产量的提高;中氮处理(N2)的茎秆强度分别比不施氮(CK)和高氮(N3)处理高36.8%和3.95%,产量分别高15.9%和0.8%,可见油用亚麻的栽培中施氮量不能过高或过低。因此,生产上采用适宜的灌溉量和施氮量是防止油用亚麻倒伏、获得高产、提高生产效益的重要措施。在本试验区,同等肥力土壤条件下,以灌溉量2 700 m3·hm-2和纯施氮量112.5 kg·hm-2为宜。