共查询到17条相似文献,搜索用时 750 毫秒
1.
玉米杂交种苗期耐低氮指标的筛选与综合评价 总被引:6,自引:0,他引:6
为探明耐低氮玉米杂交种的苗期筛选鉴定方法,筛选出耐低氮能力强、可推广应用到生产上的玉米杂交种,本研究采用蛭石和珍珠岩盆栽、Hoagland营养液培养方式,以西南地区生产中应用的51个玉米杂交种为材料,对供试品种进行了2年的低氮胁迫苗期筛选试验。结果表明:低氮胁迫对各玉米品种苗期主要形态、生理指标均有显著影响,但影响的程度在指标间和品种间均有较大差异。根据相对值变异系数大小,筛选出叶面积、氮积累量、根冠比、地上部干重、根体积、根干重和单株干重7个指标作为耐低氮能力的评价指标。以7个指标归一化的变异系数为权重进行耐低氮能力模糊隶属函数综合评价,并与用全部指标(第1年为13个指标,第2年为25个指标)模糊隶属函数评价和主成分分析法评价的结果进行比较,7个指标评价结果与全部指标综合评价结果基本一致,得出的耐低氮能力强和弱的前10个品种的重合率分别达90%和80%,说明筛选指标的代表性和评价方法的可行性。本研究表明上述7个指标可以作为玉米苗期耐低氮能力评价指标,并筛选出‘正红311’、‘成单30’、‘黔北2号’等适宜于中国西南丘陵山区种植的耐低氮品种。 相似文献
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不同耐低磷玉米自交系生长发育特征研究 总被引:6,自引:2,他引:6
采用盆栽和田间试验方法研究了低磷胁迫对不同耐低磷玉米基因型全生育期生长发育的影响。结果表明,不同自交系在生长发育过程中对低磷胁迫的反应存在明显差异,在苗期耐低磷自交系植株干重和缺磷症状的相对值显著高于敏感自交系;到拔节始期,耐低磷自交系仍无缺磷症状,而敏感自交系症状加剧;进入生殖生长期后,耐低磷自交系孕穗期上部叶干重、茎干重受低磷影响的程度显著低于敏感自交系;至吐丝期,不同自交系间的耐低磷差异除了表现在植株干重上外,穗位高、雄花分枝数、功能叶面积也出现显著差异,低磷胁迫下耐低磷自交系这几个性状的相对值均显著高于敏感自交系;在成熟期,低磷胁迫下耐低磷自交系的相对产量较大,敏感自交系的相对产量较小。受低磷影响,敏感自交系的抽雄期、抽穗期、吐丝期和散粉期都显著延迟,而耐低磷自交系受影响较小或几乎不受影响。 相似文献
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氮肥对不同耐低氮性玉米品种花后物质生产及叶片功能特性的影响 总被引:7,自引:2,他引:5
为明确不同耐低氮性玉米品种花后物质生产及叶片功能特性,采用大田试验,以玉米耐低氮品种‘正红311’和低氮敏感品种‘先玉508’为试验材料,在6个氮水平下研究花后物质生产及叶片功能特性。结果表明:施氮可显著提高玉米干物质积累、叶面积指数和叶片光合速率,延缓花后叶片叶绿素含量和全氮含量的下降,抑制生育后期叶片C/N值的增加,从而提高玉米的最终产量。耐低氮品种‘正红311’花后干物质积累、叶片光合速率、叶面积指数和产量均显著高于低氮敏感品种‘先玉508’,‘正红311’较‘先玉508’平均提高30.5%、9.2%、35.0%和8.8%。两品种吐丝后叶片叶绿素含量差异显著,耐低氮品种‘正红311’平均较低氮敏感品种‘先玉508’提高4.85%。两品种吐丝后叶片氮含量差异不大,但‘正红311’和‘先玉508’吐丝?成熟期叶片全氮含量分别下降31.5%和34.9%,‘正红311’降幅低于‘先玉508’。两品种花后叶片C/N值差异显著,‘先玉508’较‘正红311’平均提高5.95%。与低氮敏感品种‘先玉508’相比,耐低氮品种‘正红311’花后叶片光合速率更高、叶面积指数更大,而叶片叶绿素含量和全氮含量降幅与C/N值增幅更低,延缓了生育后期叶片的衰老,延长了叶片的功能期,增加干物质积累和产量。施用氮肥可有效提高‘正红311’干物质积累、叶面积指数和产量,延缓其生育后期叶片C/N值升高,而‘先玉508’需要较高的施氮水平才能维持其花后叶片光合速率和全氮含量。 相似文献
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氮高效玉米自交系的筛选指标及其子粒氮素营养特性分析 总被引:1,自引:0,他引:1
在高氮和低氮条件下,对高产氮高效型、高产氮低效型、低产氮高效型、低产氮低效型四个类型玉米自交系氮效率筛选指标进行分析。结果表明,施用氮肥后,高产氮高效型和高产氮低效型根系氮素转移量增加,对子粒氮的贡献率提高。低氮下高产氮高效型根系氮转移量对子粒氮的贡献率高于高产氮低效型,高氮和低氮条件下两种基因型子粒氮主要来源于粒重形成阶段营养体的转移,而氮素不足时高产氮高效型后期根系氮素吸收能力比高产氮低效型更具有优势。无论高氮还是低氮条件下,对高产氮高效基因型的筛选,子粒吸氮量和吐丝期茎叶总氮量是重要的辅助筛选指标。 相似文献
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玉米不同层位叶片生理生化指标与SPAD值的关系 总被引:1,自引:1,他引:0
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试验研究了不同氮水平下27个玉米自交系的氮素生产效率。结果表明,高氮和低氮水平下,高产氮高效型玉米吐丝期干物质积累量高于低产氮低效型,吐丝期氮素干物质生产效率最高。施氮后,氮素子粒生产效率和氮素干物质生产效率均下降。高氮条件下,氮素子粒生产效率与成熟期氮素干物质生产效率达到极显著正相关;低氮条件下,氮素子粒生产效率与吐丝期、灌浆期、成熟期氮素干物质生产效率呈显著相关性。高氮和低氮条件下,高产氮高效型生育后期植株氮积累量高于低产氮低效型,氮积累量的差异主要在于吐丝后氮积累,高产氮高效型生育后期根系具有强吸收能力,子粒氮素利用效率高;施氮后,后期氮吸收能力进一步增强。 相似文献
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低氮胁迫对不同耐低氮玉米品种苗期伤流液性状及根系活力的影响 总被引:5,自引:1,他引:4
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施氮模式对夏玉米产量和籽粒灌浆的影响 总被引:10,自引:1,他引:9
为进一步明确夏玉米在基肥和拔节期施肥的基础上增施吐丝肥的增产机理,于2011年在中国农业大学吴桥试验站布置了田间试验。共设置4种施氮模式:即模式Ⅰ,施氮量90 kg·hm-2(播前90 kg·hm-2);模式Ⅱ,施氮量190 kg·hm-2(播前150 kg·hm-2+拔节40 kg·hm-2);模式Ⅲ,施氮量250 kg·hm-2(播前90 kg·hm-2+拔节160kg·hm-2);模式Ⅳ,施氮量300 kg·hm-2(播前50 kg·hm-2+拔节150 kg·hm-2+吐丝100 kg·hm-2)。本研究对比分析了不同施氮模式对夏玉米产量和籽粒灌浆的影响。结果表明,在施基肥和拔节肥的基础上,再追施吐丝肥,与不施吐丝肥的模式相比,其吐丝后11~20 d、21~30 d、31~40 d内,每天增加的枯叶数分别减少0.01~0.02片、0.01~0.05片、0.02~0.04片;吐丝后穗位叶SPAD值的峰值有所提高,灌浆中后期SPAD值下降延缓;模式Ⅳ与模式Ⅲ相比灌浆速率峰值提高8.5%,籽粒体积得到显著提高。夏玉米吐丝后籽粒的吸氮量显著提高(模式Ⅳ籽粒吸氮峰值分别是模式Ⅰ、Ⅱ、Ⅲ的1.65倍、1.45倍、1.31倍),氮收获指数增加2.5~13.3个百分点,穗粒数增加。与穗粒数相比,吐丝期增施氮肥(模式Ⅳ)对千粒重的促进更显著,可改善夏玉米产量因子和部分穗部性状,与模式Ⅰ、Ⅱ、Ⅲ相比,分别增产200 kg·hm-2、300 kg·hm-2、400 kg·hm-2。夏玉米增施吐丝肥可以延缓吐丝后光合面积下降,从而为籽粒灌浆提供较多的源,最终提高粒重和产量。 相似文献
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硅磷配施对低磷土壤春玉米干物质积累、
分配及产量的影响 总被引:3,自引:3,他引:0
以玉米品种‘正红2号’和‘正红115’为材料,通过2014年和2015年的田间小区定位试验,研究低磷土壤条件下,硅磷肥配施对玉米拔节期和吐丝期的净光合速率、蒸腾速率和叶面积指数,拔节期、吐丝期、灌浆期和成熟期干物质积累和分配,产量及产量构成因素的影响,探讨施硅及硅磷配施的增产效果。结果显示,与对照(不施磷肥和硅肥)相比,施磷、施硅和硅磷配施处理均可提高玉米拔节期和吐丝期的叶面积指数和净光合速率,增加拔节期、吐丝期、灌浆期和成熟期各生育阶段的干物质积累量,降低灌浆期和成熟期叶片的干物质分配比例和灌浆期茎鞘的干物质分配比例,提高籽粒干物质分配比例和收获指数,降低秃尖长度,增加穗长,最终提高穗粒数、千粒重和籽粒产量;其中施用磷肥增加或降低上述指标的效应明显大于施用硅肥,硅磷配施增加或降低上述指标的效应又明显大于单施磷肥或单施硅肥,硅和磷表现出明显的协同作用和配合效应。2014年和2015年玉米籽粒产量均与拔节期、吐丝期、灌浆期和成熟期干物质积累量呈显著正相关;与单施磷肥相比,硅磷配施处理分别增产1 288.57 kg·hm~(-2)(2014年)和1 313.61 kg·hm~(-2)(2015年),且2015年的增幅明显大于2014年,硅、磷表现出稳定的增产效应。综上所述,在四川丘陵低磷土壤条件下,合理进行硅磷肥配施,既能提高玉米生育前期物质生产能力和干物质积累量,又能改善生育后期干物质在玉米各器官中的分配,促进籽粒灌浆结实,最终提高籽粒产量。 相似文献
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Christos Noulas Ioannis Alexiou Juan M. Herrera Peter Stamp 《Journal of plant nutrition》2013,36(8):1201-1218
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. 相似文献
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提高粮食作物中可食部分的锌生物有效性是解决人体缺锌的重要措施。为研究氮锌肥料施用对玉米籽粒锌营养的影响,本研究以郑单958和谷神玉66为试验材料,在大田条件下研究3个氮水平(90、180 和225 kg N·hm-2)和2个喷锌处理(0和4.5 kg·hm-2 ZnSO4·7H2O)下玉米籽粒产量和氮锌含量以及灌浆期叶片生理特性的变化。结果表明,吐丝后,与施氮量90 kg·hm-2处理相比,施氮量180和225 kg·hm-2处理提高了吐丝后穗位叶SPAD值及硝酸还原酶(NR)、谷氨酰胺合成酶(GS)、碳酸酐酶(CA)、超氧化物歧化酶(SOD)活性和灌浆后期PSⅡ综合性能指数(PI),降低了丙二醛(MDA)含量。施锌能提高吐丝后穗位叶CA、SOD、过氧化物酶(POD)、过氧化氢酶(CAT)活性和灌浆后期SPAD值和PI,降低MDA含量。2个品种相比,谷神玉66灌浆后期穗位叶SPAD值、叶片初始荧光(Fo)和最大荧光(Fm)较高,而灌浆前期穗位叶PI和吐丝后NR、CA、SOD以及POD活性则以郑单958较高。施氮量为90 kg·hm-2时,玉米籽粒产量平均为8.55 t·hm-2,随着施氮量增加,玉米籽粒产量显著提高。籽粒中氮含量以施氮量180 kg·hm-2时最高,为14.85 g·kg-1。施氮量90和180 kg·hm-2时,籽粒锌含量平均为27.2 mg·kg-1,显著高于施氮量225 kg·hm-2处理。与不施锌相比,喷锌后玉米籽粒产量未有显著变化,籽粒中氮、锌含量分别增加了11.7%和18.0%。郑单958籽粒产量较谷神玉66提高了3.8%,籽粒氮锌含量则分别减少了11.9%和5.3%。综合来看,施氮量为180 kg N·hm-2时,与喷施ZnSO4·7H2O 4.5 kg·hm-2 配合施用能够增强玉米灌浆期叶片SPAD和荧光特性,提高氮锌代谢关键酶活性,增强氧自由基清除系统酶活性,减弱膜脂过氧化作用的伤害,促进籽粒中氮、锌的吸收和累积。本研究结果可为玉米生产中优化锌生物强化措施提供理论依据。 相似文献
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Fanjun Chen 《Acta Agriculturae Scandinavica, Section B - Plant Soil Science》2013,63(6):565-569
Abstract Inadequate supply of nitrogen (N) fertilizers results in lower N use efficiency (NUE) and higher N losses which cause environmental deterioration, such as nitrate pollution of groundwater and emission of nitrous greenhouse gases. One way to increase NUE is to use N-efficient cultivars, which grow better under reduced N supplies. Both elite inbred lines and landraces are the basis for hybrid breeding in maize. While inbred lines are mostly selected from high N input conditions, landraces are historically distributed in poor soils with low N availability. Therefore, some potential NUE-related traits conserved in the landraces may have been lost during modern breeding processes. In the present study, the N accumulation and utilization efficiency of 15 elite inbred lines and four landraces of maize were compared at low (LN) and high N (HN) input conditions. In general, the grain yields of the inbred lines and the landraces were similar at both N rates. However, nitrogen accumulation ability in landraces was much higher than that of the inbred lines. The high N accumulation of landraces was closely related to their higher biomass, indicating that growth potential is the main driving force for N accumulation. Nevertheless, N utilization efficiency (grain produced per unit N absorbed) of the landraces was significantly lower than that in inbred lines. Correspondingly, assimilation allocation for grain formation, as indicated by the harvest index, was much lower in landraces than in inbred lines. The higher growth potential, and hence, the ability of N accumulation in landraces may be a valuable trait in breeding programs aiming to further improve N use efficiency. 相似文献
15.
Gunda Schulte auf'm Erley Nazma Begum Mosisa Worku Marianne Bänziger Walter J. Horst 《植物养料与土壤学杂志》2007,170(1):106-114
Nitrogen efficiency is a complex trait. Identification of secondary plant traits correlating with N efficiency would facilitate the breeding for N‐efficient cultivars. Sixteen tropical maize cultivars differing in grain yield at low N supply (N efficiency) under field conditions in Zimbabwe exhibited a significant negative correlation between N efficiency and leaf senescence during grain filling. The same cultivars were studied for leaf senescence under N deficiency in a short‐term nutrient‐solution experiment. Leaf chlorophyll contents as estimated by SPAD values and photosynthesis rates were used as measures for leaf senescence. Cultivars differed both in SPAD values and photosynthesis rates of the older leaves during N deprivation. Significant negative correlations were found between SPAD values, photosynthesis rates in the nutrient‐solution experiment, and leaf‐senescence scores in the field experiments, and positive correlations were found between photosynthesis rates and grain yield under low‐N conditions in the field. Relationships between physiological root parameters, which were also investigated in the nutrient‐solution experiment, and N uptake or grain yield of the cultivars in the field could not be established. It is concluded, that the assessment of the capacity of a genotype to maintain a higher photosynthetic capacity of older leaves during N deficiency–induced senescence at the seedling stage is a suitable selection parameter for the N efficiency of tropical maize cultivars. 相似文献
16.
硫肥用量对玉米氮硫吸收分配和产量的影响 总被引:4,自引:0,他引:4
为明确硫肥用量在作物增产方面的效应,本研究采用单因素随机区组设计,通过大田试验,设置5个硫肥(硫磺)用量,分别为0 kg(S)·hm~(-2)(S0)、40 kg(S)·hm~(-2)(S1)、80 kg(S)·hm~(-2)(S2)、120 kg(S)·hm~(-2)(S3)和160kg(S)·hm~(-2)(S4),研究不同硫肥用量对玉米产量和氮硫素吸收、分配的影响。结果表明,施用硫肥可使玉米产量增加7.0%~18.1%,S2处理玉米产量最高,为12 978.30 kg·hm~(-2)。施用硫肥能显著提高玉米各生育时期(除大喇叭口期外)植株干物质积累量。成熟期,玉米叶片、叶鞘、籽粒干物质积累量均在S2处理下达最大值,玉米茎秆、苞叶、穗轴干物质积累量均在S1处理下达最大值。整个生育期内,玉米硫素积累量和硫素吸收强度均在S2处理下达最大值,且显著高于不施硫的S0处理。成熟期时,玉米叶片硫素积累量随施硫量的增加而增加,S4处理时达最大值;玉米茎秆、苞叶、穗轴硫素积累量均在S1处理下最大;玉米叶鞘和籽粒硫素积累量则S2处理下最大。从拔节期至抽雄吐丝期,S3处理促进玉米氮素积累效果最佳;灌浆期和成熟期分别以S1和S2处理更有助于玉米氮素积累。施硫量的增加会在一定程度上降低玉米硫肥偏生产力和硫肥利用率;玉米硫肥农学利用率在S2处理下最大。玉米植株的氮素和硫素吸收累积量具有极显著相关关系。因此,适量的硫肥在提高玉米产量和氮硫吸收、分配及利用效率方面发挥着重要作用,施硫量为80 kg(S)·hm~(-2)时,整体效果最佳。 相似文献
17.
甜玉米氮素积累和分配的基因型差异 总被引:5,自引:2,他引:3
为了解甜玉米高产品种氮素积累和分配的规律,阐明不同生育阶段氮素积累和分配的基因型差异,及其对产量形成及氮素利用效率的作用,分析了22个甜玉米品种在同一施氮水平下拔节期、开花期和鲜食期的植株氮素积累量和分配量。结果表明,甜玉米品种不同阶段的氮素积累和分配存在着显著的基因型差异。随着生育进程的推进,植株氮素含量逐渐下降,氮素积累量逐渐上升,不同生育阶段的氮素积累量以拔节到开花期最高;氮素在开花前主要分布在叶片中,在开花后开始由叶片逐渐向果穗转移。到鲜食期,甜玉米不同品种果穗中氮素分配量最高,占全株氮素总积累量的41.32%,其次为子粒,氮素分配量占全株氮素积累量的28.53%。高产品种拔节—鲜食期氮素积累量高,鲜果穗高产品种在鲜食期叶片和子粒中的氮素分配较高,鲜子粒高产品种在鲜食期叶片和雄穗中氮素分配量较高且轴中氮素分配量较低。鲜果穗氮素利用效率高的品种主要是由于其减少了开花—鲜食期的氮素积累量,其次是减少了拔节—开花期的氮素积累量,且其在鲜食期叶片、轴和叶鞘中的氮素分配量较少。鲜子粒氮素利用效率和各阶段的氮素积累量及鲜食期各器官的氮素分配量无显著相关关系。 相似文献