包膜肥料养分控释机理研究进展

利用胶囊技术将易水溶性肥料包被起来是提高肥料利用率和减少施肥环境风险的一个重要手段,在广泛收集国内外有关包膜肥料研究的基础上,探讨了包膜肥料养分控释的原理、过程和特征,概述了影响包膜肥料养分控释的因素和包膜肥料养分控释的数学模拟研究,并提出了我国包膜肥料养分控释机理研究的主要方向。     

A retained viability index (RVI10) for evaluation of a cyanobacterial powder fertilizer

The preparation of a dry and powder fertilizer based on five nitrogen-fixing cyanobacterial strains is described. Tolypothrix tenuis and Nostoc muscorum resisted the drying and milling processes and showed a suitable recovering capacity in liquid media of different pH and salinity. Although a decrease in the cellular viability was observed with the storage time, the biomass of Nostoc muscorum retained viability for 16 months. The results were evaluated in terms of the retained viability index (RVI₁₀) specifically designed for the fertilizer material.     

复合叶面肥对油桃和葡萄生长生理及果树品质的影响

我国北方一些地区因土壤pH高,导致其中有效性微量元素含量很低而不能满足果树植物的正常生长发育,进而导致严重的缺素症。通过土壤直接施肥或通过灌溉水将化肥施入土壤,肥料中的微量元素很快会被土壤固定,因而这些方法不能有效地解决缺素症问题。作者用5年时间研制成功了应用果树植物的系列复合叶面肥,这些叶面肥不仅含有植物所需的大量元素,而且含有微量元素、有机营养及植物生长调节剂;叶面肥的配方也因果树植物种类生长习性的不同而异。以油桃和葡萄为试材,喷施复合叶面肥72h后,叶片中叶绿体含量、硝酸还原酶活性、铁和锌含量显著提高;叶面肥还能增进油桃和葡萄果实品质,促进葡萄枝芽增重,但不会引起葡萄树体徙长。整个生长季节喷施复合叶面肥对树体均有益,但喷施间隔时间不应少7-10d。     

丹参氮、磷肥效效应及最佳施肥模式研究

在陕西省商州市山阳县不同肥力土壤上,采用N、P二因素五水平最优设计,进行了丹参氮、磷优化配方施肥模式研究的多点田问试验。根据田间试验结果,求得不同土壤肥力水平下的N、P肥效反应方程,根据方程提出丹参不同产量水平的N、P合理配比和肥料用量。寻优结果表明,在山阳低肥力土壤目标产量10000～11500kg／hm^2之间的施氮为88．17～165．7kg／hm^2,施磷(P2O4)为88．18～165．7kg／hm^2;中肥力土壤目标产量在11000～14000kg／hm^2之间的施N量为108．5～187．4kg／hm^2,施磷(P2O5)为105．1～179．5kg／hm^2;高肥力土壤目标产量在20000～25000kg／hm^2之间的施N量为85．4～173．1kg／hm^2,施磷(P2O5)为121．95～179．01kg／hm^2。合理施用N、P肥有利于提高丹参产量,但过量施肥会造成丹参减产。     

Treatment by acidification followed by solid–liquid separation affects slurry and slurry fractions composition and their potential of N mineralization

The aim of the present work was to assess the effect of treatments by acidification, solid–liquid separation or acidification followed by solid–liquid separation on the physical and chemical composition of pig slurry (S) and pig slurry fractions (non acidified and acidified solid (SF and ASF) and liquid (LF and ALF) fractions), as well as on the potential of N mineralization of these pig slurry derived materials. Acidification strongly decrease the inorganic carbon content of S, SF and LF and it also affects the distribution of P, Ca and Mg between the solid and liquid fraction leading to an ALF more equilibrated than LF in terms of nutrients. Acidification increases the potential of organic N mineralization in SF and decreases the potential of N immobilization in S and LF. It can be concluded that the proposed treatment generates valuable slurry fractions with distinct characteristics and potential of N mineralization that may be incorporated to soil at different periods after sowing to comply with plant nutrient requirements.     

Trace Element Composition of Selected Fertilizers Used in Chile: Phosphorus Fertilizers as a Source of Long-Term Soil Contamination

Anthropogenic activities like agriculture have resulted in increased concentrations of some trace elements of toxicological and environmental concern in soils. Application of fertilizers has been one of the major inputs of these contaminants to agricultural soils in developing countries. Twenty-two fertilizers, including straight nitrogen (N), phosphorus (P), potassium (K), and NK fertilizers and micronutrient sources, were analyzed by inductively coupled plasma optical emission spectrometry (ICP-OES) for arsenic (As), cadmium (Cd), cobalt (Co), chromium (Cr), copper (Cu), iron (Fe), manganese (Mn), molybdenum (Mo), nickel (Ni), lead (Pb), vanadium (V), and zinc (Zn). As expected, the trace element content of fertilizers was highly variable and related to the origin of the material. Phosphorus fertilizers, especially triple superphosphate, presented the highest As, Cd, Cu, Cr, Ni, V, and Zn concentrations. In some of these fertilizers, the Cr, V, and Zn contents reached values greater than 3475 mg kg^?1 of P, and the Cd content (up to 288 mg kg^?1 of P) was several times higher than the regulatory limits of different countries. Some micronutrient sources presented the highest concentrations of Mn and Pb. In the cases of N, K, and NK fertilizers, the trace element concentration was very low, sometimes below the detection limits. In some agricultural systems the input of trace elements such as As and Cd to the soil through P fertilizers application may be higher than the outputs through plant uptake and leaching; therefore the long-term use of these fertilizers may cause the trace element concentration to increase in the plow layer of agricultural soils.     

Effects of elevated CO2 concentration, supplemental irrigation and nitrogenous fertilizer application on rain-fed spring wheat yield

It is expected that the CO₂ concentration of the Earth’s atmosphere will reach 600–1000 ppm by the end of the 21st century. Therefore, in this study, we evaluated the effects of elevated CO₂ concentrations on the development of rain-fed spring wheat in an attempt to identify a practical pathway to increase crop production. To accomplish this, a field experiment was conducted at Guyuan Experimental Station in a semiarid region of China during 2005–2007. During this experiment, the CO₂ concentration was increased to 40.0 ppm and supplemental irrigation and nitrogenous fertilizer (N fertilizer) were applied. The experimental results showed that the elevated CO₂ concentration significantly improved the thousand-grain weight and the grain number per spike. Furthermore, supplemental irrigation and N fertilizer application during the elongation and booting stage of rain-fed spring wheat in conjunction with an elevated CO₂ concentration improved the water use efficiency (WUE), nitrogen use efficiency (NUE), thousand-grain weight, and the yield by 14.6%, 39.6%, 9.3%, and 14.7%, respectively, when compared to groups subjected to the same treatment but not grown under elevated CO₂ concentrations. Furthermore, the spring wheat yield was improved by 81.8% in response to an elevated CO₂ concentration, 60 mm of supplemental irrigation and applied N fertilizer (37.5 g m^?2 NH₄NO₃). However, the presence of an elevated CO₂ concentration without supplemental irrigation and N fertilizer only resulted in an increase in the wheat yield of 7.8%. Consequently, the combination of elevated CO₂ concentration, supplemental irrigation and N fertilizer application played an important role in the improvement of WUE, NUE, thousand-grain weight, and grain yield of rain-fed spring wheat in this region.     

Chemical, microbiological and plant analysis of soil fertilized with alkaline hydrolysate of sheep’s wool waste

Summary The effect of adding alkaline hydrolysate of sheep’s wool waste on the chemical and microbiological properties of a park soil (Sofia, Bulgaria) has been assessed in a 9 month laboratory experiment. The waste product contained 75–80% water-soluble materials: peptides, amino acids, salts, dyes, lipids, some carbohydrates, potassium ions, and it seemed likely that the hydrolysate obtained could be used as a harmless and valuable fertilizer in agriculture. It was demonstrated that the organic material positively influenced microbial soil populations and ryegrass growth. As the remaining partially degraded keratin is highly dispersed it should act as a slow release fertilizer thus feeding plants additionally. The results suggest that the wool hydrolysate is beneficial for improving soil characteristics and could successfully be used as alternative biofertilizer. The authors hope that by utilization of the keratin wastes, the environment around leather and fur plants could be influenced positively and that the expense of removing the wastes to controlled landfill sites and part of the expenses for sustaining the latter will be saved.     

磷肥对花生根系形态、生理特性及产量的影响

采用池栽, 测定不同施磷量对花生(Arachis hypogaea)根系性状、生理特性及产量的影响。结果表明: (1)结荚中期, 根系总长度、体积、表面积及根尖数量均随施磷量的增加而增加, 在施磷30-90 kg·hm^-2范围内, 施磷比不施磷4项指标分别增加3.5%-20.7%、9.3%-21.9%、9.7%-20.3%和12.6%-21.4%。特别是当施磷量超过60 kg·hm^-2时, 上述4项指标均显著高于不施磷处理; 施磷可使根系中超氧化物歧化酶(SOD)、过氧化物酶(POD)、过氧化氢酶(CAT) 3种酶活性分别提高12.7%-20.6%、14.8%-36.8%和17.0%-41.8%, 丙二醛(MDA)含量降低8.4%-19.5%, 根系活力和可溶性蛋白含量分别提高10.4%-25.0%、29.2%-53.5%; 同时, 施磷可使单株根瘤数量和鲜重分别增加10.7%-21.7%和22.6%-35.6%。(2)收获期, 除MDA含量随施磷量的增加而增加, SOD、POD和CAT活性, 根系活力和可溶性蛋白含量均随施磷量增加而呈降低趋势, 但多数指标施磷与不施磷及不同施磷量之间差异不显著。造成这一现象的原因与施磷后花生荚果库容增大, 对光合产物需求量增加, 导致植株和根系营养不良, 加速衰老有关。(3)花生单株结果数、生物产量、经济系数、出米率及产量均随施磷量的增加而增加, 其中产量的增加主要是通过生物产量和经济系数协同提高来实现的。     

Nonlinear response of nitric oxide fluxes to fertilizer inputs and the impacts of agricultural intensification on tropospheric ozone pollution in Kenya

Crop yields in sub‐Saharan Africa remain stagnant at 1 ton ha^?1, and 260 million people lack access to adequate food resources. Order‐of‐magnitude increases in fertilizer use are seen as a critical step in attaining food security. This increase represents an unprecedented input of nitrogen (N) to African ecosystems and will likely be accompanied by increased soil emissions of nitric oxide (NO). NO is a precursor to tropospheric ozone, an air pollutant and greenhouse gas. Emissions of NO from soils occur primarily during denitrification and nitrification, and N input rates are a key determinant of emission rates. We established experimental maize plots in western Kenya to allow us to quantify the response function relating NO flux to N input rate during the main 2011 and 2012 growing seasons. NO emissions followed a sigmoid response to fertilizer inputs and have emission factors under 1% for the roughly two‐month measurement period in each year, although linear and step relationships could not be excluded in 2011. At fertilization rates above 100 kg N ha^?1, NO emissions increased without a concomitant increase in yields. We used the geos‐chem chemical transport model to evaluate local impacts of increased NO emissions on tropospheric ozone concentrations. Mean 4‐hour afternoon tropospheric ozone concentrations in Western Kenya increased by up to roughly 2.63 ppbv under fertilization rates of 150 kg N ha^?1 or higher. Using AOT40, a metric for assessing crop damage from ozone, we find that the increased ozone concentrations result in an increase in AOT40 exposure of approximately 110 ppbh for inputs of 150 kg N ha^?1 during the March–April–May crop growing season, compared with unfertilized simulations, with negligible impacts on crop productivity. Our results suggest that it may be possible to manage Kenyan agricultural systems for high yields while avoiding substantial impacts on air quality.