磷素水平对大豆氮素积累及产量的影响

利用砂培方法和15N示踪技术研究了磷素水平对大豆氮素积累、根瘤固氮和产量的影响。结果表明:大豆植株氮素积累、根瘤固氮和产量均随磷素营养水平的提高而呈单峰曲线变化,营养液磷素浓度31mg/L左右时达到峰值,当营养液磷素浓度达11mg/L时,再提高磷素浓度对大豆根瘤固氮率无明显促进作用;而对于大豆植株氮素积累、根瘤固氮量和产量,只有当营养液磷素浓度达到21mg/L时,再提高磷素浓度才无明显促进所用,表明满足根瘤固氮的磷素营养水平较产量形成的水平要求低。     

氮素营养水平对大豆氮素积累及产量的影响

以“东农47”为试材,采用15N 标记的 (NH4)2SO4作为氮源,利用砂培方式研究了氮素营养水平对大豆氮素积累及产量的影响。结果表明,随外源氮水平增加,大豆植株氮素积累量和产量呈先增加后降低的变化趋势,当营养液氮浓度为50 mg/L时,植株氮素积累量和子粒产量最大。在 R4和 R5 期补充氮肥的供给明显增加植株对氮的积累,并能显著提高大豆产量。大豆生长需要一定量的“启动氮”,“启动氮”的作用维持到V3期对大豆氮的积累和产量形成效果最好。随外源氮水平增加,大豆吸收外源氮的比例增加,根瘤固氮所占比例降低,外源氮和根瘤固氮积累量随外源氮水平增加呈先增加后降低的变化趋势。当氮浓度为100 mg/L时,有利于植株对外源氮的吸收,当氮浓度为50 mg/L时,有利于根瘤固氮的积累,“启动氮”的作用维持到V3期根瘤固氮的积累明显增加; 在R4和R5期补充外源氮的供给可以显著增加对外源氮利用,以R5期效果最好。     

施氮对大豆根系形态和氮素吸收积累的影响

采用框栽试验方法研究了不同施氮水平对大豆根系形态和氮素吸收积累的影响,结果表明:不同施氮水平对大豆植株生物量、氮素吸收积累量及根系形态有显著影响,随施氮量增加,植株干重、氮素积累量、单株产量等均呈先增加后降低趋势,其中以N100[100 kg(N)·hm-2]处理效果最佳,总体表现为N100>N200>N50>N25>N0.无N(NO)和适量偏低的氮(N25、N50)增加了大豆的根冠比,但过多的氮(N200)反而降低了大豆的根冠比,说明低氮胁迫促进了大豆根系的生长.大豆根长、根表面积和根体积随施氮量的增加表现为先降后增而后又降低的规律,不施氮(N0)情况下,根长、根表面积和根体积均高于低氮处理(N25、N50),之后随施氮量增加而增加,当超过一定施氮量(N200)时又呈降低趋势.不同生育时期植株生物量、氮素积累、根长、根表面积和根体积等表现为花期>苗期>鼓粒期.因此施用一定量氮肥对大豆植株生物量、氮素积累以及根系形态等产生显著影响,进而影响大豆氮素转运量和转运效率,最终影响大豆籽粒产量和品质.     

施氮对不同氮效率类型玉米自交系产量、干物质及氮素积累的影响

以前期筛选出的低氮高效型玉米自交系(PH6WC)和低氮低效型玉米自交系(ZY118)为试验材料,设置N0(0 kg/hm2)、N90(90 kg/hm2)、N180(180 kg/hm2)和N360(360 kg/hm2)4个氮处理,研究不同氮效率类型玉米自交系产量、干物质积累、氮素积累及氮素代谢相关酶活性对氮浓度的响...     

施氮对水稻产量、氮素利用及土壤无机氮积累的影响

通过田间试验研究了不同施氮量(0、60、120、180和240 kg hm~(-2))对水稻氮肥利用、产量、土壤氮素供应及氮素平衡的影响,结果表明,水稻产量随施氮量的增加呈先增后降的趋势,当施氮量超过180 kg hm~(-2)后产量下降,根据水稻产量(y)和施氮量(x)拟合,得出最佳施氮量为204 kg hm~(-2)。施用氮肥可显著增加水稻氮吸收总量,并随施氮量的增加显著增加,当施氮量超过180 kg hm~(-2)后,氮吸收总量不再显著增加。氮肥当季回收率、农学利用率、偏生产力和生理利用率均随施氮量的增加而下降,分别由44.0%、25.5 kg kg~(-1)、145.6 kg kg~(-1)和58.1 kg kg~(-1)下降至31.1%、13.6 kg kg~(-1)、43.6 kg kg~(-1)和43.7 kg kg~(-1)。氮收获指数表现为随施氮量的增加先增后降,以施氮量180 kg hm~(-2)处理最高,为68.7%。土壤无机氮(Nmin)含量在水稻整个生育期呈现先快速下降后缓慢升高的趋势,施氮处理各层土壤Nmin积累量与不施氮处理差异均达显著水平(P0.05),且基本随着施氮量的增加而增加。水稻成熟期土壤残留Nmin量和表观损失均随施氮量的增加而增加。氮盈余主要以土壤Nmin残留量为主,表观损失在氮盈余比例较小,但随着施氮量的增加显著增加。水稻氮吸收量、土壤无机氮残留量和氮素表观损失量与施氮量呈显著的正向相关性。在本试验条件下,综合水稻产量、氮肥利用效率和土壤无机氮积累等方面的因素,在吉林省水稻主产区,适宜施氮量应控制在180~204 kg hm~(-2)范围内。     

不同生育期大豆品种氮素积累特性研究

为研究不同生育期大豆品种的氮素积累特性,以10 个在黑龙江省哈尔滨地区生育期不同的大豆品种为试验材料,利用15N 示踪技术,在框栽条件下分析大豆植株全氮累积规律,以及不同氮素来源,即土壤氮、肥料氮和根瘤氮的积累和分配规律。结果表明:不同生育期大豆品种全株和各器官的全氮积累量,除了根部,均表现为晚熟品种＞中熟品种＞早熟品种,不同生育期品种间差异显著;不同生育期大豆品种土壤氮和肥料氮占全氮比例与生育期负相关,即早熟品种＞中熟品种＞晚熟品种,不同生育期品种营养器官中土壤氮和肥料氮比例高于荚皮和籽粒;不同生育期大豆品种根瘤固氮量和占全氮比例与生育期正相关,即晚熟品种＞中熟品种＞早熟品种,根瘤氮主要积累在大豆荚皮和籽粒中,分配到籽粒中的根瘤氮占全株根瘤氮积累量的76.38% ～ 92.25%。本研究为丰富不同生育期大豆品种氮素积累特性及氮肥调控提供数据支持。     

锰胁迫对大豆氮素积累的影响

采用15N示踪技术与沙培相结合的方法,以最适锰浓度为对照,设置锰缺乏(分别为对照浓度的1/25和1/5作为重度和轻度锰缺乏处理)和锰过量(分别为对照浓度的5倍和25倍作为轻度和重度锰过量处理)4个锰胁迫处理,研究了锰胁迫对大豆氮素积累的影响。结果表明:与对照相比,锰胁迫并未明显影响生育前期大豆植株氮素积累,但对中后期氮素积累起显著抑制作用(P0.01),并且抑制作用随胁迫程度的加深而加重;锰胁迫对苗期(V4)肥料氮的积累无影响,但对其他生育时期肥料氮的积累均表现出不同程度的抑制作用;在整个生育期间,锰胁迫显著抑制了根瘤固氮的积累,大幅度减少了鼓粒期间根瘤固氮的积累;锰胁迫不仅显著减少了成熟期(R8)大豆营养器官和子粒中肥料氮、根瘤固氮、总氮的积累,还在一定程度上增加了营养器官中肥料氮、根瘤固氮、总氮的积累比例,子粒则相应减小。综合分析表明,锰胁迫对大豆肥料氮、根瘤固氮、以及总氮的积累均有抑制作用,抑制效果在大豆生育中后期表现明显,并且锰胁迫改变了成熟期大豆营养器官和子粒中肥料氮、根瘤固氮和总氮的积累比例。本试验所得结果丰富了锰胁迫与大豆氮素营养的相关研究内容,并为进一步的机理研究奠定了基础。     

叶面施氮对不同类型大豆品种氮素积累与分配的影响

为研究大豆不同类型品种叶面氮素吸收、积累与分配规律,以黑龙江省三江平原大豆主栽4种类型品种为试验材料,采用15N示踪法在大豆R5期进行叶面施氮,探究不同施氮量及品种类型各器官对标记氮素积累与分配规律.结果表明,在4.5 kg?hm-2施氮量条件下,大豆各器官干物质量、氮素积累量及15N积累量总体均达到最高,不同类型品种...     

施氮水平对烤烟根冠平衡及氮素积累与分配的影响

在盆栽条件下,设不施氮（CK）,每株施N 5.45g（N1）和8.18g（N2）3个施氮水平,运用15N示踪技术,研究了不同施氮量条件下烤烟根冠平衡及氮素在不同器官间的积累与分配。结果表明,移栽至打顶期烤烟地上部干物质累积量随施氮量增加而增加,根系干物质积累量以N1处理最高;打顶至成熟期地上部干物质累积量N1处理最高,根系干物质积累量随施氮量增加而增加。打顶期根冠比随施氮量增加而降低,成熟期根冠比随施氮量增加而提高。打顶至成熟期烟株氮素积累量以N1处理最高;期间N1处理各器官均有一定氮素积累,而 N2处理和CK下部叶及中部叶有一定量的氮素输出。打顶期氮素在根系中的分配比例随施氮量增加而降低。随施氮量增加,烤烟积累的氮素中来自肥料氮的比例增加;积累的肥料氮中来自基肥氮的量增加。在本试验条件下,施氮（N）5.45 g/plant可促进根冠平衡,使烟株稳健生长。     

麦?豆轮作体系周年施氮量对夏大豆氮素利用效率和产量的影响

  【目的】  探明伊犁河谷麦?豆轮作体系下施氮对夏大豆氮素利用及产量的影响,筛选出夏大豆高产的周年施氮组合。  【方法】  于2016—2018年在新疆伊宁县进行小麦?大豆轮作田间试验。前茬冬小麦设4个施氮水平,分别为0、104、173、242 kg/hm2,即WN0、WN1、WN2、WN3处理;在小麦各处理基础上,再设夏大豆3个施氮水平,分别为0、69、138 kg/hm2,即SN0、SN1、SN2处理。从大豆出苗后20天起,每10天取一次植株样,测定不同部位的氮素含量和生物量,收获期测产量及其构成,计算夏大豆的氮素利用效率。  【结果】  前茬麦季及大豆当季施氮量均显著影响夏大豆干物质及植株氮素积累量。在麦季施氮0～173 kg/hm2范围内,夏大豆当季施氮有利于增加植株干物质积累量及各器官氮素积累量,且小麦季施氮水平越低,夏大豆当季施氮对干物质积累及植株氮素积累的作用越显著。在麦季施氮量为173 kg/hm2时,夏大豆季施氮可增加产量,且以SN1处理产量最高;而当小麦季施氮量为104和242 kg/hm2时,夏大豆季SN1和SN2处理产量之间没有显著差异。在前茬小麦季施氮的基础上,夏大豆当季氮肥吸收利用率、农学利用率及偏生产力均随当季施氮量的增加而降低。  【结论】  在伊犁河谷冬小麦?夏大豆轮作体系下,前茬麦季施氮173 kg/hm2基础上,夏大豆当季施氮69 kg/hm2可获得较为理想的夏大豆产量和氮素利用效率。     

施肥水平对冬大麦干物质和氮素积累与转运的影响

为合理利用氮肥,进一步提高大麦产量和品质,以扬饲麦3号、港啤1号、扬农啤2号和Frankin共4个品种为供试材料,研究了0(CK),90(NL),180(NM)和270kg/hm2(NH)4个氮肥水平下冬大麦干物质和氮素积累、转运及对籽粒贡献的规律。结果表明,随着施氮量的提高,大麦干物质花前积累量呈增加趋势,积累率及对籽粒的贡献率呈下降趋势,各器官的转运量在NM处理(180kg/hm2)范围内呈增加趋势,高于此范围则下降。氮素营养花前积累量和转运量各品种均呈上升趋势,花前积累率、转运率和对籽粒氮的贡献率都呈下降趋势。不同品种不同氮肥处理下大麦干物质转运量以茎秆为最大,转运率大部分以芒壳+穗轴为最高,对籽粒的贡献率以茎秆为最高。各器官氮素转运量以叶片最高,转运率以芒壳+穗轴最大,氮素转运对籽粒的贡献率以叶片最高。大麦各品种籽粒产量与施氮量呈二次曲线关系,氮素积累量与施氮量呈显著线性正相关关系。表明在本试验条件下,大麦最高产量的最佳施氮范围为212.42～261.97kg/hm2。     

EFFECTS OF NITROGEN FORMS ON THE GROWTH AND POLYAMINE CONTENTS IN DEVELOPING SEEDS OF VEGETABLE SOYBEAN

A pot culture experiment of nitrogen forms [nitrate (NO^? ₃ ): ammonium (NH ⁺ ₄ )] with four ratios (100:0, 75:25, 50:50, and 25:75) in nutrient solutions was conducted to examine the effect of nitrogen forms on the growth and polyamine contents of developing seeds of vegetable soybean [Glycine max (L.) Merr. cv. ‘Li-xiang 95-1′]. Results showed that the best plant growth vigor was observed in (75%), and then in (50%). However, the fresh and dry weight of biomass decreased when a high concentration of either (100%) or (75%) was the primary nitrogen source in the nutrient solution. The numbers of flowers and pods in (75%) were significantly decreased compared with other ammonium-nitrate ratios in which the numbers of flowers and pods were not influenced by nitrogen forms. During the development of seeds, levels of free Put and Spd decreased, and the decrease extents were more marked in 100:0 and 25:75 (:), but the change of free Spm was opposite. Levels of conjugated and bound polyamines in all nitrogen forms increased, but the increases in 75:25 and 50:50 (:) were not so obvious as in 100:0 and 25:75 (:) treatments. The possible roles of polyamines in the adaptive mechanism of vegetable soybean seeds to different nitrogen forms were discussed.     

氮素水平对不同氮效率基因型水稻的物质生产与分配的影响

研究了在群体水培条件下,3种氮素水平(5、15和25mg.kg-1)对6种不同氮效率利用基因型迟熟中粳水稻物质生产与分配的影响。结果表明:氮素水平、基因型对水稻氮素干物质生产效率(NUEdm)、氮素籽粒生产效率(NUEg)均有极显著的影响。6种不同氮效率基因型可分成氮高效和氮低效利用型2类。NUEdm在2类基因型水稻中总体上均随着氮素水平升高呈现上升趋势;而NUEg在氮低效基因型中表现为随氮素浓度升高而先升后降。在水稻的4个关键生育期,不同氮素水平、2类基因型之间水稻干物质积累量差异显著。成熟期,氮素水平对水稻茎鞘、根、穗的干物质分配比例影响显著,对叶片干物质分配比例影响不显著。相同氮素水平下,就平均值而言,水稻茎鞘、叶片、根系干物质比例均表现为氮低效基因型>氮高效基因型,而穗的干物质比例均表现为氮高效基因型>氮低效基因型。氮素水平对不同基因型水稻产量影响显著,同一氮素水平下均表现为氮高效型基因型水稻产量显著高于氮低效型基因型,且施氮量越大差异越大。相关分析表明,水稻各关键生育期的干物质生产量、产量、每穗粒数均与氮素水平、基因型的NUEg、NUEdm显著或极显著相关,与成熟期水稻各器官干物质分配比例相关性则相对较弱。     

改良剂对玉米和大豆间作植株锌铬积累的影响

通过盆栽试验,研究改良剂石灰和过磷酸钙对玉米、大豆间作植株各器官锌铬积累的影响。结果表明,不同改良剂处理后,能显著降低土壤中锌、铬有效态含量,植株各器官锌含量为:对照>低浓度石灰>高浓度石灰;铬含量为:对照>高浓度过磷酸钙>低浓度过磷酸钙,单作>间作。在间作下施用低浓度过磷酸钙改良效果最优,其中玉米根、茎、叶的锌、铬含量分别比只施用低浓度过磷酸钙单作降低30.72%、35.96%和29.51%,69.98%、64.21%和51.56%;比不施加改良剂的对照间作玉米降低55.57%、59.68%和66.57%,64.10%、76.79%和80.75%;大豆根、茎、叶的锌、铬含量分别比其只施用低浓度过磷酸钙单作降低0.26%、4.91%和16.42%,14.25%、8.16%和23.33%,比不施加改良剂的对照间作降低63.95%、69.54%和65.49%,54.15%、57.14%和57.14%。间作条件下,低浓度过磷酸钙处理在不增加大豆对锌铬吸收的前提下,大幅降低玉米对重金属的吸收,显著增加玉米产量。     

INFLUENCE OF ORGANIC AND MINERAL FERTILIZATION ON GERMINATION,LEAF NITROGEN,NITRATE ACCUMULATION AND YIELD OF VEGETABLE AMARANTH

The influence of manure and diammonium phosphate (DAP) mineral fertilizer on germination, leaf nitrogen content, nitrate accumulation and yield of vegetable amaranth (Amaranthus hypochondriacus) was investigated. Field trials were set up at the University of Nairobi Field Station at the Upper Kabete Campus during the long rains of March–May in 2007 and 2008. Trials were laid out as complete randomized block design with four fertilization treatments: 20, 40, and 60 kg nitrogen (N) ha^?1 supplied by DAP (18:46:0), 40 kg N ha^?1 supplied by cattle manure and an unfertilized control variant. The vegetables were harvested at three maturity stages at 6, 7, and 8 weeks after planting. Results indicated that there were significant differences between treatments in germination percentage, leaf nitrogen content, nitrate accumulation and vegetable yield. Plants that received manure had a higher germination percentage than those that received the same amount of N supplied by the chemical fertilizer DAP. The yields generally increased from week 6 to week 8. The highest yield was recorded in plots receiving 40 kg N ha^?1 from DAP at eight weeks after planting. Plots that were supplied with manure recorded the lowest yield when compared to the fertilizer treated plots at all rates. Leaf nitrogen content increased with increasing rate of N but only when N was supplied by DAP fertilizer. The leaf nitrogen content decreased with increasing age of the plants. The leaf nitrate content increased with increase in DAP application rate. Results indicate that manure application produced quality vegetables in terms of low nitrate levels, but leaf nitrogen and vegetable yields were low. DAP application effected higher yields, but the vegetables had high though acceptable nitrate levels.     

施氮模式对春玉米养分累积特性的影响

通过田间试验,研究了施氮模式对春玉米养分累积特性的影响.结果表明,施氮明显提高了春玉米干物质和NPK的累积量及累积速度,这种影响均在拔节期以后更明显.随着生育期推进,春玉米干物质及NPK的累积量均增加,但增加幅度不同.干物质及NP累积量的增加幅度在大喇叭口期以前较小,大喇叭口期以后较大;K累积量的增加幅度则正好相反,大...     

太湖地区黄泥土氮肥对水稻产量、叶片碳氮同化及不同土层氮的影响

在长期定位试验的基础上研究了太湖地区黄泥土不同施氮水平对水稻产量、碳氮同化及不同土层氮的影响。结果表明，长期施氮量（N）在161．0kg hm^-2处理和高于该施氮量处理的产量之间没有显著差异。拔节期、孕穗期和灌浆期施氮量在161．0kg hm^-2处理和高于该施氮量处理的碳氮同化水平之间几乎没有差异，但都高于施氮量在57．5kg hm^-2处理的。不同土层氮分布结果表明，长期施氮量在161．0kg hm^-2和高于该施氮量各处理中，长期施入有机肥配施NPK肥处理残留最深，其次是长期施入化肥N的处理，长期秸秆还田配施N肥处理较浅。     

IMPACT OF LOW RATES OF NITROGEN APPLIED AT PLANTING ON SOYBEAN NITROGEN FIXATION

Environmental conditions in the northern Great Plains can delay emergence, nitrogen (N) fixation and growth of soybean due to cool and wet soil conditions at planting. The objective was to evaluate the impact of low rates of N applied at planting on soybean N fixation and crop growth. A field experiment was established within corn soybean rotation using a split-plot design with four replications. Whole plots were no-tillage and conventional tillage and split plots were starter fertilizer. Nitrogen sources were ammonium nitrate or urea applied at four rates. The amount of plant N fixation increased with growth stage reaching a maximum fixation at the R5 growth stages. Plant ureide content decrease with increase N applied for all growth stages except R7. The increase in plant biomass contributed to an overall increase in yield indicating that in unfavorable environments application of N at planting can have a positive impact on soybean growth.     

COURSE OF DRY MATTER AND NITROGEN ACCUMULATION OF SPRING WHEAT GENOTYPES KNOWN TO VARY IN PARAMETERS OF NITROGEN USE EFFICIENCY

Field experiments were conducted for two years to compare and identify bread spring wheat (Triticum aestivum L.) genotypes which make the most efficient use of nitrogen (N). Such information is required for breeding strategies to reverse the negative relationship between yield and protein content. Three Swiss spring wheat cultivars (‘Albis’, ‘Toronit’, ‘Pizol’) and an experimental line (‘L94491’) were grown without (N0; 0 kg N ha^?1) and with high fertilizer N [(NH₄NO₃); (N1; 250 kg N ha^?1) supply on a clay loam soil with low organic matter content. Biomass and nitrogen accumulation in biomass as well as the leaf growth and senescence patterns (SPAD) were investigated in an attempt to explain the physiology of growth and N translocation of these genotypes. The pre-anthesis accumulation of biomass and N in the biomass depended on genotype only at N1 in 2000. In this year, conditions were less favorable for the pre-anthesis accumulation of biomass and N, which was, on average, 10 and 20% lower, respectively, of the total than in 1999. The contribution of pre-anthesis assimilates to the grain yield (CPAY) was higher in 1999 for all genotypes (36.9%) compared to 2000 (13.5%) except ‘Toronit’. Between anthesis and maturity the climate influenced the genetic variability of some N use efficiency components: N translocation efficiency (NTE) and dry matter translocation efficiency (DMTE). NTE was higher in 1999 (68.1%) compared to 2000 (50.7%); 1999 was a year in which the post-anthesis period was drier and warmer than usual. ‘Toronit’ produced the highest biomass by maturity due mainly to greater and longer lasting green leaf area after anthesis. ‘Albis’ performed relatively well under low input conditions, with considerable amounts of N being re-translocated to the seeds at maturity (NHI), whereas ‘Pizol’ accumulated in grains N as high as for ‘L94491’. In a humid temperate climate breeding for greater N uptake and partitioning efficiency may be a promising way to minimize N losses and produce high phytomass and grain yields. Using high protein lines as selection material and combining them with high biomass genotypes may lead to high protein contents without decreasing yield.