水肥(氮)对小麦生理生态的影响 (Ⅰ)水肥 (氮 )条件对小麦光合蒸腾与水分利用的影响

光合速率在日出后随着光强的增强而急速升高,4月20日是小麦光合最强。净光合速率日变化随施氮量的增加而下降,水胁迫处理显著低于高水处理;不同时段变化净光合速率随施氮量和土壤含水量的增加而增加,但总的趋势是降低的。小麦蒸腾速率日变化总体趋势是在日出后随着光强的增强而急速升高、随光强的减弱而降低。小麦蒸腾速率日变化曲线为单峰型,中午最高。叶片蒸腾速率日变化随土壤水分供应增加而增加,随氮肥供应增加而下降;不同供水供氮条件下,叶片蒸腾速率的分异在日中尤其是上午比较明显。蒸腾速率从4月10日一直呈现下降趋势。小麦叶片水分利用率日变化曲线为"L"型,即早上较高,中午和下午都非常低。4月20日叶片水分利用率最高,5月10日最低。叶片对不同土壤水分和氮控制的反映为高氮低水高水分利用率,反之,则水分利用率较低。不同水、氮在上午对叶片水分利用率影响差异比较明显,下午则趋于一致。     

三江平原典型湿地土壤中硫的分布特征

本文以三江平原的三种典型类型湿地:小叶樟(Calamagrostisangustifolia)草甸、毛果苔草(Carexlasiocarpa)沼泽、乌拉苔草(Carexmeyeriana)沼泽为研究对象,对其土壤中硫的含量在水平及垂直变化方面进行分析。研究在自然环境下硫的分布特征。经过试验分析和数据处理,得出以下结论:总硫、水溶性硫、吸附性硫、盐酸可溶性硫、盐酸挥发性硫、有机硫含量均为小叶樟草甸<乌拉苔草沼泽<毛果苔草沼泽;别拉洪河、挠力河、鸭绿河、浓江是三江平原四条有代表性的沼泽性河流,流域土壤中的硫素含量为挠力河>鸭绿河>浓江>别拉洪河;在土壤层次上,具有明显的规律性:除盐酸挥发性硫以外,其余各硫组分自上而下含量呈递减趋势;在湿地土壤各形态硫中,有机硫是土壤总硫的主体,盐酸挥发性硫含量最低。总硫与有机硫相关性最显著,达极显著正相关(P=0.01),水溶性硫与盐酸可溶性硫的相关性最差。影响湿地土壤中硫素含量的因素为土壤有机质、土壤pH值、物理粘粒及氧化-还原条件。     

土壤重金属污染现状与修复技术研究进展

阐述了土壤重金属污染物的来源和重金属污染土壤修复技术研究现状,分析了各种修复技术的优缺点、实用性与发展动态,为土壤重金属污染综合治理与修复提出了新的思路。     

开垦对草甸土有机碳的影响

本文利用经典统计学和地统计学相结合的方法,选取科尔沁沙地东南缘草甸土两块10×10m的样地为例,分析了草地开垦8a后的耕地耕作层土壤有机碳含量和空间分布格局的变化,结果表明:草地与耕地表层(0～10cm)土壤有机碳含量差异不显著,草地亚表层(10～20cm)土壤有机碳含量低于耕地(p<0.05);草地与耕地表层和亚表层土壤有机碳空间分布格局具有明显差异,表现为草地的表层和亚表层的结构异质性分别大于耕地,分数维小于耕地,空间依赖性强于耕地,空间分布格局的破碎程度弱于耕地。耕地表层与亚表层土壤有机碳含量差异不显著(p<0.05),但空间结构特征和空间分布格局存在明显的差异;而草地表层与亚表层土壤有机碳含量差异显著(p<0.05),但空间结构特征和空间分布格局比较相似。因此,开垦不仅影响草甸土有机碳含量的高低,而且影响其空间结构特征和分布格局。这对进一步了解草地开垦对土壤有机碳及全球碳循环和气候变化的影响具有重要意义。     

磷在富营养化湖泊沉积物-水界面的循环

沉积物中部分固定的磷可通过分解或溶解作用而释放磷酸盐到沉积物间隙水中;再生的磷可能释放到上覆水体中,或在沉积物中作为一种自生相而再沉淀,或被沉积物的其它组分所吸附。本文描述了磷在沉积物-水界面的迁移过程,并对影响磷循环的因子及其磷自沉积物释放的机制作一简要概述。     

设施栽培条件下土壤养分及有机质组成变化趋势的研究

以黄泛平原壤质潮土不同年限的设施栽培土壤为研究对象,探讨了设施栽培条件对土壤养分及土壤有机质组成的影响。结果表明,设施栽培土壤碱解氮、速效磷、速效钾、盐分含量均明显高于大田,其含量主要取决于施用化学肥料的种类和数量,随栽培年限的增加而增加;土壤有机质、腐殖酸、胡敏酸含量随种植年限有升高趋势;HA/FA与栽培年限显著相关,表示设施栽培条件下,土壤熟化程度随有机肥料的逐年施用而有所提高,但HA/FA变化幅度不大,这可能与设施栽培形成的高温高湿条件及施用有机肥料中难分解物质的含量有关。     

湖南衡南县紫色土土壤动物研究

通过对衡南县紫色土5种生境中的土壤动物进行调查研究,共获得土壤动物1657只,隶属于4门9纲37目,其中优势类群2类,常见类群11类。探讨了5种生境中土壤动物群落结构特征,并进行了多样性、均匀性及相似性分析。     

旱稻水分利用率与碳同位素识别值之间的关系

通过温室盆栽试验 ,分析和探讨了三个水平的土壤水分条件对分蘖期和成熟期收获的旱稻(OryzasativaL .)生物量累积、水分利用率 (WUE)、植株不同部位的碳同位素识别值 (CID)的影响 ,并了解了它们之间的相互关系。水分条件包括 :饱和含水量 (W1 )、饱和含水量的 70 %(W2 )、饱和含水量的 4 0 %(W3)。结果表明当土壤水分条件从W1降低到W2时 ,分蘖期收获的生物量降低 4 5 %左右 ,成熟期收获的生物量降低 1 6 %～ 1 9%;而当从W1降低到W3时 ,分蘖期收获的生物量降低 73%左右 ,成熟期收获的生物量降低 5 5 %～ 5 7%。然而 ,根据地上部干重计算而来的WUE(WUE 地上部 )和根据全株干重计算而来的WUE(WUE 全株 )则随土壤含水量的降低而增加 ,其增幅在分蘖期为 0 .0 7～ 0 .2 8gkg-1 ,在成熟期为 0 .0 7～ 0 .4 5gkg-1 。植株的CID值变幅为 1 7.0～ 2 0 .6 ,但植株不同部位间差别显著 ,分蘖期收获的样品CID值从小到大的顺序为 :根 <最近完全伸展叶 <叶芽 <茎秆 ;而成熟期收获的样品CID值从小到大的顺序为 :籽粒 <根 <茎秆 <旗叶。随着土壤含水量的降低 ,植株所有部位的CID值亦显著减小。叶部的CID值与WUE 地上部(和WUE 全株 )之间呈一致的负相关关系。     

Comparative effects of applying leguminous and non-leguminous green manures and inorganic N on biomass yield and nitrogen uptake in flooded rice (<Emphasis Type="Italic">Oryza sativa</Emphasis> L.)

The beneficial role of green manures in rice production is generally ascribed to their potential of supplying plant nutrients, particularly nitrogen (N). However, the mechanisms through which green manures enhance the crop productivity are poorly understood. Pot experiments were conducted using a ¹⁵N-tracer technique: (1) to compare the biomass production potential of sesbania (Sesbania aculeata Pers.) and maize (Zea mays L.) as green manuring crops for lowland rice and (2) to compare the effect of the two types of green manure and inorganic N on the dry matter accumulation and N uptake by two rice (Oryza sativa L.) cultivars, viz. IR-6 and Bas-370. Although maize produced three times higher shoot biomass compared with sesbania, the latter showed higher N concentration; and thus the total N yield was similar in the two types of plants. Applying the shoot material of the two plants to flooded rice significantly enhanced the dry matter yield and N uptake by the two rice cultivars, the positive effects generally being more pronounced with sesbania than with maize amendment. The difference in the growth-promoting potential of the two plant residues was related more to an increased uptake of the native soil N rather than to their direct role as a source of plant-available N. A positive added nitrogen interaction (ANI) was observed due to both plant residues, the effect was much more pronounced with the application of sesbania than with maize residues. In both rice cultivars, inorganic N also caused a substantial ANI, particularly at higher application rate. Losses from the applied N were 2–3 times lower from sesbania, compared with maize treatment. Green manuring with sesbania also caused much lower N losses than the inorganic N applied at equivalent or higher rates. The overall benefit of green manuring to rice plants was higher than inorganic N applied at comparable rates. The two rice cultivars differed in their response to green manuring, IR-6 generally being more responsive than Bas-370.     

Fractal features of soil particle size distribution and the implication for indicating desertification

Some of the effects of land desertification on soil properties are manifested by the coarsening of the soil particlesize distribution (PSD) and the losses in organic C and nutrients. The changes and characteristics of PSD and selected chemical properties in soils at the 0-15 cm plough layer from different degrees of desertified croplands are analyzed in the semiarid Horqin Sandy Land, northern China. The fractal dimension of the PSD is emanated to characterize the patterns of PSD. The relationships between the fractal dimension of the PSD and selected soil properties are discussed. The results show that: (1) in the transformation from potential desertified cropland to extremely desertified cropland, the sand content at the 0-15 cm soil increased from 69% to 93%, organic C and total N contents decreased by 65% and 69%, respectively; (2) the fractal dimension of PSD ranged from 2.179 to 2.611, the more the contents of sand, the lower the fractal dimension and the higher the desertified degree of farmland. In the desertification process within the studied area, the mean fractal dimension decreased from 2.555 for the potential desertified soils to 2.298 for extremely desertified soils; (3) there existed considerable linear relationships between fractal dimension and soil properties. It was shown that fractal dimensions of PSD are useful parameters able to monitor soil degradation and to estimate the degree of soil desertification.