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1.
在冬小麦-夏玉米一年两熟模式下,玉米品种“郑单958”(植株密度9株/m^2)和小麦品种“93-9”(基本苗704株/m^2),冬小麦基施144kg N/hm^2,研究了玉米5个施N量(0、90、180、270和360kg/hm^2)对后茬小麦期间土壤剖面硝态氮含量、无机氮总量,以及小麦氮素吸收利用和产量的影响.结果表明:(1)与不施氮相比,玉米施氮显著增加小麦季0~200cm土壤硝态氮含量;自拔节起,0~40cm、0~130cm和0~200cm硝态氮含量均随施氮量增加而递增,在硝态氮含量较高的小区增幅也大.(2)轮作一周期后,不施氮和施氮360kg/hm^2显著影响0~130cm和0~200cm无机氮总量,但在90~270 kg/hm^2之间,施氮量的影响不明显.(3)施氮小于180kg/hm^2时,成熟期小麦植株氮素和籽粒氮素积累量、氮肥利用率均随施氮量增加而递增,但不明显.(4)与不施氮相比,施氮90kg/hm^2的小麦产量和麦玉轮作总产均增加但不明显,施氮180 kg/hm^2均显著增加,施氮270kg/hm^2与180kg/hm^2无明显差异.本试验条件下,夏玉米施氮90~180 kg/hm^2是适宜的.  相似文献   

2.
采用开顶式气室,通过土培盆栽实验研究了不同大气CO2浓度(背景空气浓度375μmol·mol-1和倍增浓度750μmol·mol-1)和氮素水平(不施氮和施氮0.25 g/kg)下两个冬小麦品种(小偃6号和小偃22)主要生育期(拔节、孕穗、扬花、灌浆期)叶片叶绿素含量和荧光动力学参数的变化.结果显示,与背景CO2浓度相比,在不施氮条件下大气CO2浓度倍增处理的小麦叶片出现明显的光合下调现象,而施氮时变化不明显;同时,CO2浓度倍增后小麦各主要生育期叶片叶绿素含量均有不同程度地下降,荧光参数初始荧光(F0)值明显提高,最大荧光(Fm)、可变荧光(Fv)、最大光能转换效率(Fv/Fm)和PSⅡ潜在活性(Fv/F0)值均显著降低.施氮可提高冬小麦各个时期叶片叶绿素含量、Fm、Fv、和Fv/F0值,降低F0值;不施氮条件下,大气CO2浓度倍增对冬小麦各主要生育时期叶绿素含量和荧光参数的影响明显,而施氮后影响微弱.研究表明,大气CO2浓度升高对冬小麦光合速率、叶绿素含量和光系统Ⅱ(PSⅡ)的光合电子传递和潜在活性具有一定抑制作用,通过施氮可以有效地缓解其负面效应.  相似文献   

3.
灌溉量和施氮量对冬小麦产量和土壤硝态氮含量的影响   总被引:3,自引:1,他引:2  
Jiang DY  Yu ZW  Xu ZZ 《应用生态学报》2011,22(2):364-368
研究了大田条件下灌溉量和施氮量对小麦产量和土壤硝态氮含量的影响.结果表明:增加灌溉量,0~200 cm土层硝态氮含量呈先降后升又降的趋势.0~80 cm土层硝态氮含量显著低于对照,而80~200 cm土层硝态氮含量显著高于对照.随灌溉量的增加,土壤硝态氮向深层运移加剧,在成熟期,0~80 cm土层硝态氮含量降低,120~200 cm土层硝态氮含量升高,并在120~140 cm土层硝态氮含量出现高峰.灌溉量不变,施氮量由210 kg·hm-2增加到300 kg·hm-2,开花期、灌浆期、成熟期0~200 cm各土层土壤硝态氮含量显著升高.随灌溉量的增加,小麦籽粒产量先增加后降低,以全生育期灌溉量为60 mm的处理籽粒产量最高.增加施氮量,籽粒产量、蛋白质含量和蛋白质产量显著提高.本试验中,施氮量为210 kg.hm-2、两次灌溉总量为60 mm的处理籽粒产量、蛋白质含量、蛋白质产量和收获指数均较高,且土壤硝态氮损失少,是较合理的水氮运筹模式.  相似文献   

4.
赵俊晔  于振文 《生态学报》2006,26(3):815-822
在土壤肥力不同的两块高产田上,利用15N示踪技术,研究了高产条件下施氮量对冬小麦氮肥吸收利用、籽粒产量和品质的影响,及小麦生育期间土壤硝态氮含量的变化.结果表明:1.成熟期小麦植株积累的氮素73.32%~87.27%来自土壤,4.51%~9.40%来自基施氮肥,8.22%~17.28%来自追施氮肥;随施氮量增加,植株吸收的土壤氮量减少,吸收的肥料氮量和氮肥在土壤中的残留量显著增加,小麦对肥料氮的吸收率显著降低;小麦对基施氮肥的吸收量、吸收率和基施氮肥在土壤中的残留量、残留率均显著小于追施氮肥,基施氮肥的损失量和损失率显著大于追施氮肥;较高土壤肥力条件下,植株吸收更多的土壤氮素,吸收的肥料氮量较少,土壤中残留的肥料氮量和肥料氮的损失量较高,不同地块肥料氮吸收、残留和损失的差异主要表现在基施氮肥上.2.当施氮量为105 kg/hm2时,收获后0~100cm土体内未发现硝态氮大量累积,随施氮量增加,0~100cm土体内硝态氮含量显著增加;施氮量大于195 kg/hm^2时,小麦生育期间硝态氮呈明显的下移趋势,土壤肥力较高地块,硝态氮下移较早,下移层次深.3.随施氮量增加,小麦氮素吸收效率和氮素利用效率降低,适量施氮有利于提高成熟期小麦植株氮素积累量、籽粒产量和蛋白质含量;施氮量过高籽粒产量和蛋白质含量不再显著增加,甚至降低;较高土壤肥力条件下,获得最高籽粒产量和蛋白质含量所需施氮量较低.  相似文献   

5.
水培硝态氮浓度对冬小麦幼苗氮代谢的影响   总被引:3,自引:1,他引:2  
门中华  李生秀 《广西植物》2010,30(4):544-550
以Hoagland营养液为培养基质,以冬小麦为试材,动态测定高(含NO3--N15mmol·L-1)、中(含NO3--N7.5mmol·L-1)、低(含NO3--N2.5mmol·L-1)三种氮水平处理条件下硝态氮的吸收和累积、硝酸还原酶活性、铵态氮含量、小麦吸氮量及根系活力,分析不同供氮水平对冬小麦硝态氮吸收、还原、转运的影响,探讨不同供氮条件下,植物地上、地下部分硝态氮代谢的变化。结果表明:水培条件下,营养液NO3-的消耗量、pH变化、植株全氮以及根系活力均能较好地反映不同氮水平对植株硝态氮代谢的影响;高氮条件下植物体内NO3-进一步同化较中氮弱,冬小麦植株积累了较多的NO3-,而非过多的吸收营养液中的NO3-。不同氮浓度处理下,NO3-的供应与植株NRA间无相关关系,根系与地上部的变化曲线不同;NO3-供应浓度高时,植物地上部是主要同化部位;低浓度时根部是主要同化部位。虽然NO3-是一种安全的氮源,但供应过高则抑制体内硝态氮进一步同化,而供应过低,植物吸收NO3-量不足、根系活力下降,不利于小麦幼苗氮素营养。  相似文献   

6.
土壤硝态氮时空变异与土壤氮素表观盈亏研究Ⅰ.冬小麦   总被引:35,自引:9,他引:26  
周顺利  张福锁  王兴仁 《生态学报》2001,21(11):1782-1789
不同氮肥用量下对冬小麦生育期间土壤硝态氮时空变化特征及土壤氮素表观盈亏量的研究结果表明,氮肥用量不同,硝态氮分布特征有差异,并且随着冬小麦的生长,其变化也不同。在冬小麦快速生长阶段,作物吸收可在一定深度的土层出现硝态氮亏缺区。由于灌溉的影响,土壤表层硝态氮向深层淋洗严重,即使在低氮肥水平,土壤深层仍可观察到硝态氮含量升高现象,存在淋出2m土体的可能性。并且氮肥用量越高,土壤硝态氮含量越高,硝酸盐向深层淋洗也越严重,淋出2m土体的可能性和也相应增大;在冬小麦生长前期(播种-拔节),即使在不施氮肥处理也有土壤氮素的表观盈余,随着施肥量的增加,在拔节-扬花也出现了土壤氮素表观盈余,而扬花后各个氮肥处理均出现土壤氮素的表观亏缺,氮肥用量越高,小麦一生中土壤表观氮盈余量越大,1m土体内平均最大盈余量达199.8kgN/hm^2。研究表明,土壤氮损失是盈余氮素的一个主要去向,而硝态氮淋洗是冬小麦生育期间土壤氮素损失的一个重要的途径。  相似文献   

7.
叶类蔬菜的硝态氮累积及成因研究   总被引:50,自引:0,他引:50  
王朝辉  田霄鸿  李生秀 《生态学报》2001,21(7):1136-1141
在菜园土壤上进行的田间试验,用禾谷类作物冬小麦作比较,研究了菠菜、小白菜、大青菜和油菜等叶类蔬菜累积硝态氮的特点,结果表明:硝态氮累积是一般早作作物的共性,苗期更为明显,无论蔬菜还是冬小麦均有较高的硝态氮含量(367.8-1413.4μg/g);但随生育期后延,蔬菜的硝态氮含量波动升高,冬小麦波动降低,盆栽试验表明,施入土壤的氮肥是蔬菜硝态氮累积的主要来源,过量施用氮肥所导致的蔬菜硝态氮吸收与还原转化不平衡是产生累积的根本原因,吸收与生长不协调更使累积过程加剧。  相似文献   

8.
施氮量对小麦/玉米带田土壤水分及硝态氮的影响   总被引:4,自引:0,他引:4       下载免费PDF全文
杨蕊菊  柴守玺  马忠明 《生态学报》2012,32(24):7905-7912
通过田间试验研究了河西绿洲灌区典型的小麦/玉米间作群体不同施氮量(0、210、420和630 kg/hm2)对小麦、玉米带田土壤水分和硝态氮(NO3(-)-N)的动态的影响.结果表明:小麦/玉米总籽粒产量随着施氮量的增加而增加,但当施氮量超过420kg/hm2时,总籽粒产量不再随施氮量增加而增加,最高总籽粒产量可达13661-14668 kg/hm2.水分利用效率在施氮420 kg/hm2时最高可达21.25 kg·hm-2·mm-1.小麦收获后,0-120 cm土层内土壤含水量随施氮量增加而减少,NO3(-)-N的累积量随施氮量增加而增加,并且表层土壤(0-60 cm) NO3(-)-N含量明显高于深层土壤(60-200 cm).在小麦/玉米整个生育期,土壤硝态氮的变化呈双峰曲线.施氮0和210 kg/hm2的土壤硝态氮第一峰值和第二峰值均分别出现在小麦三叶期和玉米大喇叭口期;施氮420和630 kg/hm2的土壤硝态氮第一峰值出现在小麦挑旗期,第二峰值分别出现在玉米大喇叭口期和玉米灌浆期.因此,在该地区小麦/玉米间作栽培模式下,施氮水平控制在420 kg/hm2时,使混合产量达到最高,同时可减轻土壤硝态氮的累积和运移,从而达到高效、安全的目的.  相似文献   

9.
同一时期的大豆品种长农5号植株中硝态氮含量是,主茎大于叶柄大于叶片,前二者中硝态氮含量随着生育进程逐渐减少,生育前期由基部向上逐渐增加,鼓粒期以后各节位间无明显变化。营养生长期间,叶片中硝态氮含量较高,不同生殖生长期间或同一时期的不同节位变化不明显。硝酸还原酶活力是成熟叶片中低,幼嫩叶片中高,且随着生育进程逐渐降低。  相似文献   

10.
菠菜叶片中硝态氮还原与叶柄中硝态氮累积的关系   总被引:2,自引:2,他引:0  
测定了不同生长期在不同施氮水平下3个菠菜品种各器官的硝态氮含量、叶片的硝酸还原酶活性、叶片细胞硝态氮的贮存库和代谢库大小.结果表明:叶柄中硝态氮含量远高于其它器官,其含量与叶片内源/外源硝酸还原酶活性的比值呈负相关;叶片细胞中硝态氮代谢库的大小与叶柄中硝态氮含量之间没有确定的关系.  相似文献   

11.
不同种类氮素对苋菜硝酸盐积累及分配的影响   总被引:1,自引:0,他引:1  
应用15N核素示踪技术,研究了不同氮肥种类对苋菜硝酸盐积累与分配的关系及氮素的去向。结果表明:(1)苋菜可食部分中茎较叶更易富集硝酸盐,茎中硝酸盐含量为叶中的1.5倍左右,施用硝态氮肥苋菜叶与茎中的硝酸盐含量都偏高。(2)苋菜硝酸盐主要来源于土壤,达到80%以上,而来自肥料部分不足20%。(3)苋菜施用尿素其肥料利用率达到46.27%,土壤残留氮素达到17.01%,均高于硫铵与硝酸钠,尿素损失率为40.32%,远低于硫铵与硝酸钠,表明施用尿素有利于土壤氮素储量的保持和提高。  相似文献   

12.
以紫球藻为研究对象,探讨了在不同硝酸钠浓度下紫球藻超氧化物歧化酶(SOD)、过氧化氢酶(CAT)的变化及一氧化氮(NO)的产生情况。研究表明紫球藻在12 mmol/L硝酸钠培养时生长良好,8 mmol/L次之,4、16 mmol/L培养时细胞产量略低。在硝酸钠培养过程中,NO的含量呈先上升、后下降、再上升的趋势,但各浓度培养时差异不大。SOD、CAT的含量对16 mmol/L硝酸钠及无氮条件较敏感,但SOD的含量整体上比CAT含量高。  相似文献   

13.
以大田试验获得的大麦氮敏感基因型BI-45为材料,利用溶液培养方法,测定了苗期株高、根长、叶绿素含量、含氮量、谷氨酰胺合成酶和硝酸还原酶活性,以及与氮代谢相关的基因(GSI-GSl-2、GSI-3、GS2、Narl、NRT2.J、NRT2-2、NRT2-3和NRT2-4)的表达。结果表明:相对于正常供氮,氮饥饿胁迫下,BI-45根和叶中的氮素利用率提高,含氮量降低,叶绿素含量减少,根冠比增加;叶片中的谷氨酰胺合成酶活性和硝酸还原酶的活性高于根,但是,与叶中的相比,根中的谷氨酰胺合成酶活性升高及硝酸还原酶活性降低的差异性更显著;与正常供氮相比,氮饥饿处理下,根中基因傩家族,基Narl和硝酸盐转运蛋白基因NRT2家族的相对表达量皆达到显著性差异,其中GSl-I、GSl-2和NRT2-2在苗期大麦氮饥饿处理下表现尤为突出,并且在6h都有上调表达。  相似文献   

14.
Increases in the deposition of atmospheric nitrogen (N) influence N cycling in forest ecosystems and can result in negative consequences due to the leaching of nitrate into groundwaters. From December 1995 to February 1998, the Pan-European Programme for the Intensive and Continuous Monitoring of Forest Ecosystems measured forest conditions at a plot scale for conifer and broadleaf forests, including the performance of time series of soil solution chemistry. The influence of various ecosystem conditions on soil solution nitrate concentrations at these forest plots (n = 104) was then analyzed with a statistical model. Soil solution nitrate concentrations varied by season, and summer concentrations were approximately 25% higher than winter ones. Soil solution nitrate concentrations increased dramatically with throughfall (and bulk precipitation) N input for both broadleaf and conifer forests. However, at elevated levels of throughfall N input (more than 10 kg N ha–1 y–1), nitrate concentrations were higher in broadleaf than coniferous stands. This tree-specific difference was not observed in response to increased bulk precipitation N input. In coniferous stands, throughfall N input, foliage N concentration, organic layer carbon–nitrogen (C:N) ratio, and nitrate concentrations covaried. Soil solution nitrate concentrations in conifer plots were best explained by a model with throughfall N and organic layer C:N as main factors, where C:N ratio could be replaced by foliage N. The organic layer C:N ratio classes of more than 30, 25–30, and less than 25, as well as the foliage N (mg N g–1) classes of less than 13, 13–17, and more than 17, indicated low, intermediate, and high risks of nitrate leaching, respectively. In broadleaf forests, correlations between N characteristics were less pronounced, and soil solution nitrate concentrations were best explained by throughfall N and soil pH (0–10-cm depth). These results indicate that the responses of soil solution nitrate concentration to changes in N input are more pronounced in broadleaf than in coniferous forests, because in European forests broadleaf species grow on the more fertile soils.  相似文献   

15.
Nitrogen yields from undisturbed watersheds in the Americas   总被引:19,自引:11,他引:8  
Yields of total fixed nitrogen and nitrogen fractions are summarized for thirty-one watersheds in which anthropogenic disturbance of the nitrogen cycle, either through land use or atmospheric deposition, is negligible or slight. These yields are taken as representative of background conditions over a broad range of watershed areas, elevations, and vegetation types. The data set focuses on watersheds of the American tropics, but also includes information on the Gambia River (Africa) and some small watersheds in the Sierra Nevada of California. For the tropical watersheds, total nitrogen yield averages 5.1 kg ha–1 y–1. On average, 30% of the total is particulate and 70% is dissolved. Of the dissolved fraction, an average of 50% is organic and 50% is inorganic, of which 20% is ammonium and 80% is nitrate. Yields are substantially lower than previously estimated for background conditions. Yields of all nitrogen fractions are strongly related to runoff, which also explains a large percentage of variance in yield of total nitrogen (r2=0.85). For total nitrogen and nitrogen fractions, yield increases at about two-thirds the rate of runoff; concentration decreases as runoff increases. There is a secondary but significant positive relationship between elevation and yield of DIN. Ratios DON/TDN and PN/TN both are related to watershed area rather than runoff; DON/TDN decreases and PN/TN increases toward higher stream orders. The analysis suggests for tropical watersheds the existence of mechanisms promoting strong homeostasis in the yield of N and its fractions for a given moisture regime, as well as predictable downstream change in proportionate representation N fractions. Yields and concentrations for small tropical watersheds are much larger than for the few temperate ones with which comparisons are possible.  相似文献   

16.
B. J. Atwell 《Plant and Soil》1992,139(2):247-251
Two cultivars of Lupinus angustifolius L. were grown in a glasshouse in solutions containing NO3 -, NH4 + or NH4NO3 with a total nitrogen concentration of 2.8 M m-3 in each treatment. One cultivar chosen (75A-258) was relatively tolerant to alkaline soils whereas the other (Yandee) was intolerant to alkalinity. Controlled experiments were used to assess the impact of cationic vs. anionic forms of nitrogen on the relative performance of these cultivars. Relative growth rates (dry weight basis) were not significantly different between the two cultivars when grown in the presence of NO3 -, NH4 + or NH4NO3. However, when NO3 - was supplied, there was a modest decline in relative growth rates in both cultivars over time. When plants grown on the three sources of nitrogen for 9 days were subsequently supplied with 15NH4NO3 or NH4 15NO3 for 30 h, NH4 + uptake was generally twice as fast as NO3 - uptake, even for plants grown in the presence of NO3 -. Low rates of NO3 - uptake accounted for the decrease in growth rates over time when plants were grown in the presence of NO3 -. It is concluded that the more rapid growth of 75A-258 than Yandee in alkaline conditions was not due to preferential uptake of NH4 + and acidification of the external medium. In support of this view, acidification of the root medium was not significantly different between cultivars when NH4 + was the sole nitrogen source.  相似文献   

17.
以桔梗(Platycodon grandiflorum)为试验材料,通过盆栽试验研究了等氮条件下6种氮素形态及铵硝氮配比(NH+4 N/NO-3 N=100∶0、75∶25、50∶50、25∶75、0∶100、CO(NH2)2)对桔梗根中硝酸盐、亚硝酸盐动态积累以及营养、药用品质的影响。结果显示:(1)桔梗根中硝酸盐及亚硝酸盐积累量以铵硝比为25∶75处理下最低;硝酸盐积累量随栽培时间的增长呈上升趋势,尤其在10月采收时显著增加,亚硝酸盐变化趋势则与之相反。(2)桔梗根中Vc含量在全硝态氮处理下最高,可溶性多糖含量在铵硝比为50∶50处理下最高,而可溶性蛋白及总游离氨基酸含量均在铵硝比为75∶25处理下达到最大值。(3)桔梗根中N、Cu、Mn、Zn积累量在酰胺态氮处理下最高,其Fe、Mg、Cu积累量在铵硝比为75∶25处理下最大。(4)桔梗根中总黄酮含量随营养液中硝态氮比例增加而呈下降趋势,并在酰胺态氮处理下达到最大;桔梗多糖及桔梗总皂苷含量均在铵硝比为25∶75处理下有最大值。研究发现,在铵硝比为25∶75处理下,桔梗根中硝酸盐及亚硝酸盐含量最低,桔梗多糖及总皂苷积累量最高,且Vc、游离氨基酸等品质指标含量也较高,有利于桔梗品质的提升;由于10月采收时桔梗根中硝酸盐含量显著增高,桔梗采收前不宜大量追施氮肥。  相似文献   

18.
基于液泡膜质子泵的硝态氮再利用研究进展   总被引:1,自引:0,他引:1  
全面掌握洛川果园的土壤水分环境特征,不仅可为苹果的园址选择、砧穗组合和改进土壤水分管理措施提供理论依据,而且对我国苹果产区果园提质增效具有借鉴价值.采用定点土壤水分连续监测法,对洛川苹果园的总体土壤水分环境以及不同生长年限、不同立地类型和乔、矮化果园的土壤水分分异特征进行分析.结果表明: 苹果树根际区 (0~200 cm)土壤水分普遍亏欠,且0~60 cm土层的水分亏欠小于60~200 cm土层;生长季0~60 cm土层贮水量与降水量的变化一致,土壤相对含水量大多<60%,季节性旱象严重;果园剖面土壤含水量变异系数随土壤深度加深而递减;随果园生长年限的增大,土壤剖面贮水量下降;在栽培密度一致的条件下,矮化果园5 m土层土壤含水量均高于乔化果园,而栽培密度大的矮化果园的土壤贮水量低于栽培密度小的乔化果园;塬地成龄果园的土壤水分含量最高,川地次之,台地相对较低.密度对果园土壤水分含量有很大影响,在栽培密度一致的条件下,采用矮化栽培能减少土壤水分消耗,显著提高果园土壤含水量;挖株降低栽培密度是维持苹果园土壤水分平衡、实现可持续发展的有效途径.  相似文献   

19.
蔬菜硝酸盐含量测定方法的改进   总被引:1,自引:0,他引:1  
针对水杨酸消化比色法测定植物体内硝酸盐含量中存在的问题,经过优化筛选,将此测定方法的提取条件优化为:温度90℃、时间30 min;每10 g绿色蔬菜加入0.2 g活性炭能消除颜色的影响,回收率达到96%。  相似文献   

20.
土壤盆栽油菜、小白菜和菠菜的叶柄对施氮的响应最为敏感。叶柄中硝态氮的累积量占整株蔬菜的一半以上(从54,9%到75.0%)。叶柄中硝态氮累积量与植物整株的硝态氮累积量呈极显著正相关。  相似文献   

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