局部高浓度硝酸盐供应对玉米根系 形态及氮累积的影响

以郑单958和鲁单981为研究对象,进行水培分根试验,在正常供水和水分胁迫条件下,分别以均匀低浓度硝酸盐处理主根和种子根(LPR-LSR)、局部高浓度硝酸盐处理主根（HPR-LSR）和局部高浓度硝酸盐处理种子根（LPR-HSR）,测定分析根系形态、生物量以及氮含量。结果表明：与氮低效鲁单981相比,氮高效郑单958具有较高的主根根长、根表面积、根系生物量、地上部生物量和氮累积量。水分胁迫条件下,郑单958和鲁单981的主根的根长、根表面积、根体积、地上部生物量和氮累积量总体上均低于正常水分条件。玉米主根和种子根对局部高浓度硝酸盐的反应存在差异。与均匀低浓度硝酸盐处理相比,局部高浓度硝酸盐处理促进正常水分条件下主根和种子根根系的生长,尤其是根长和根系表面积;在正常水分条件下,主根根长和根系表面积增加幅度范围为6.8%~27.3%和1.9%~21.9%,除HPR-LSR处理条件下的郑单958外,种子根根长和根系表面积增加幅度范围为30.4%~92.7%和10.5%~135.1%;在水分胁迫条件下,主根根长和表面积增加幅度范围为24.6%~152.9%和62.1%~229.9%,然而种子根根长降低了10.0%~29.9%,表明水分胁迫会影响种子根对高浓度硝酸盐的响应。除水分胁迫条件下LPR-HSR处理外,局部高浓度处理可同时增加两侧根系的生物量和氮累积量。无论是正常供水还是水分胁迫,与LPR-LSR处理相比,局部高浓度硝酸盐供应均能够增加地上部生物量以及氮累积量,在LPR-HSR处理条件下,增加幅度范围分别在35.0% ~107.9%和162.9%~291.1%,在HPR-LSR处理条件下分别为56.7%~109.4%和204.1%~377.0%,HPR-LSR处理条件下增加幅度较大,表明在氮素非均匀分布环境中,当主根处于高浓度硝酸盐区域时将会更显著促进生物量的增加和氮累积。     

硝酸稀土对菠菜中毒死蜱残留的降解作用研究

菠菜是我国蔬菜出口的重要品种之一,其毒死蜱残留量直接关系到我国农产品的出口和消费者的安全.采用气相色谱法(GC-NPD)测定毒死蜱残留量,研究了硝酸稀土对菠菜中毒死蜱残留动态的影响.结果表明,不论是喷施农药之前2 d还是喷施农药之后2d喷施硝酸稀土,不同的硝酸稀土对菠菜中的毒死蜱残留都有不同程度的降解作用,且随着喷药后时间的延长,毒死蜱在菠菜中的残留量逐渐减少.不同时间喷施硝酸稀土,对菠菜中毒死蜱残留降解的效果存在差异,药后喷施的效果优于药前喷施.在硝酸稀土种类的选择上,首先选择对毒死蜱降解效果好的硝酸铈和硝酸钕,其次选择常乐益植素和硝酸镧.根据稀土农用的安全性分析,参考植物性食品中稀土最大残留限量标准,选择硝酸稀土作为农药残留降解制剂用于蔬菜安全生产,在技术上是可行的,人类食用是安全的.     

The efficiency of nitrogen in cattle manures when applied to a double‐annual forage cropping system

The use of cattle manure (CM) for fertilization presents challenges for optimizing nitrogen (N) use. Our work aimed to assess N efficiencies, in a 6‐year experiment with three biennial rotations of four crops: oat–sorghum (first year) and ryegrass–maize (second year) in a rainfed humid Mediterranean area of Spain. Fertilization treatments included the following: control (no N), 250 kg mineral N ha^?1 year^?1 (250MN), three CM rates (supplying 170, 250 and 500 kg N ha^?1 year^?1) and four treatments where the two lowest CM rates were complemented with either 80 or 160 kg mineral N ha^?1 year^?1. Treatments were distributed randomly in each of three blocks. Maximum dry‐matter yield (~44–49 t ha^?1 rotation^?1) was achieved in the third rotation, and only the control and the 170CM yielded significantly less. Within the limitations of the EU Nitrate Directive, the N steady state supply of 170CM always requires a complement of mineral N (80 kg N ha^?1) to maximize N agronomic efficiency. The maximum N‐fertilizer replacement value (250CM vs. 250MN) was 0·67, without significant differences between the two treatments in other N‐related efficiency indexes, which indicates that plants took advantage of residual‐N effects. Nitrogen losses by leaching in the 250CM treatment were around 5–7% of the N applied. This reinforces the sustainability of manure recycling in long cropping seasons.     

INFLUENCE OF SALINITY AND AMMONIUM: NITRATE RATIO ON GROWTH,PHOTOSYNTHESIS, FATTY ACID AND THE ACTIVITY OF ANTIOXIDATIVE ENZYMES IN CANOLA

The effects of sodium chloride (NaCl) salinity (0 and 200 mM) and ammonium (NH₄):nitrate (NO₃) ratios (100:0, 25:75, 50:50, and 75:25) on growth, photosynthesis, fatty acids and the activity of antioxidative enzymes were investigated in canola plants. Leaf area and fresh and dry weights of leaves were significantly reduced by the salinity. The reduction in vegetative characteristics varied in both salinized and unsalinized plants according to the NH₄:NO₃ ratios so that the lowest reduction was observed with the 50:50 (NH₄:NO₃) ratio. Increased NH₄ up to 50 percent (50:50) of total N, promotes the yield at both salinized and unsalinized plants. In both salinized and unsalinized plants, the increased NH₄ and NO₃ ratio in the nutrient solution reduced the photosynthetic (Pn) rate and stomatal conductance; however, the reduction in Pn rate was severely impaired at a higher ratio of NH₄ in the nutrient solution. In both salinized and unsalinized plants, the 75:25 ratio had the lowest potassium (K) and sodium (Na) content; however, the K/Na ratio was the highest in 50:50 ratio. An increase of NH₄ in the solution led to a significant increase in NH₄ content in both salinized and unsalinized plants. Salinity increased NH₄ content so that the salinized plant had nearly twice as high NH₄ content in the leaves. The activity of nitrate reductase was increased by increasing NH₄ from 0 to 50% and then reduced at a higher ratio of NH₄ in the solution. The activities of antioxidative enzymes increased in salinized plants regardless of the NH₄:NO₃ ratios. In salinized plants, the activities of superoxide dismutase and catalase enzymes were increased by 44.4 % and 97.5%, respectively. Within salinized and unsalinized treatments, the highest activities of all antioxidant were observed in 75:25 ratio, while they remained unchanged for all NH₄:NO₃ ratios. The increased NH₄ content in the solution increased the oil content and the maximum oil content in both salinized and unsalinized plant was obtained in both 50:50 and 75:25 ratios. The percentage of oleic acid was affected by both salinity and NH₄:NO₃ ratios. The ratios of NH₄:NO₃ had no effect on the protein content; however, salinity reduced the protein content by 20%.     

Improving in-season nitrogen recommendations for maize using an active sensor

An active crop canopy reflectance sensor could be used to increase N-use efficiency in maize (Zea mays L.), if temporal and spatial variability in soil N availability and plant demand are adequately accounted for with an in-season N application. Our objective was to evaluate the success of using an active canopy sensor for developing maize N recommendations. This study was conducted in 21 farmers’ fields from 2007 to 2009, representing the maize production regions of east central and southeastern Pennsylvania, USA. Four blocks at each site included seven sidedress N rates (0–280 kg N ha⁻¹) and one at-planting N rate of 280 kg N ha⁻¹. Canopy reflectance in the 590 nm and 880 nm wavelengths, soil samples, chlorophyll meter (SPAD) measurements and above-ground biomass were collected at the 6th–7th-leaf growth stage (V6–V7). Relative amber normalized difference vegetative index (ANDVI_relative) and relative SPAD (SPAD_relative) were determined based on the relative measurements from the zero sidedress treatment to the 280 kg N ha⁻¹ at-planting treatment. Observations from the current study were compared to relationships between economic optimum N rate (EONR) and ANDVI_relative, presidedress NO₃ test (PSNT), or SPAD_relative that were developed from a previous study. These comparisons were based on an absolute mean difference (AMD) between observed EONR and the previously determined predicted relationships. The AMD for the relationship between EONR and ANDVI_relative in the current study was 46 kg N ha⁻¹. Neither the PSNT (AMD = 66 kg N ha⁻¹) nor the SPAD_relative (AMD = 72 kg N ha⁻¹) provided as good an indicator of EONR. When using all the observations from the two studies for the relationships between EONR and the various measurements, ANDVI_relative (R² = 0.65) provided a better estimate of EONR than PSNT (R² = 0.49) or SPAD_relative (not significant). Crop reflectance captured similar information as the PSNT and SPAD_relative, as reflected in strong relationships (R² > 0.60) among these variables. Crop canopy reflectance using an active sensor (i.e. ANDVI_relative) provided as good or better an indicator of EONR than PSNT or SPAD_relative, and provides an opportunity to easily adjust in-season N applications spatially.     

Performance and environmental effects of forage production on sandy soils. III. Energy efficiency in forage production from grassland and maize for silage

Based on experimental data gathered in a research project on nitrogen fluxes in intensive dairy farming in Northern Germany, an analysis of fossil energy input and energy efficiency in forage production from permanent grassland and maize for silage was conducted. Field experiments comprised different defoliation systems and different rates of mineral N fertilizer and slurry application. Each change from grazing to cutting in grassland systems reduced the energy efficiency. Energy efficiency consistently decreased with increasing rates of mineral N application. In the production of maize for silage, maximum energy efficiency was obtained with an application of 50 kg N ha^?1 from slurry only. Net energy yields of maize for silage were much higher than that of grassland when compared at the same level of fossil energy and nitrogen fertilizer input. Considering both nitrate‐leaching losses and a necessary minimum quantity of grass herbage in a well‐balanced ration, it is suggested that a high proportion of maize for silage in combination with N‐unfertilized grass/clover swards used in a mixed cutting/grazing system represents a good trade‐off between the leaching of nitrates and energy efficiency.     

The effect of water table depth on emissions of N2O from a grassland soil

Nitrous oxide (N₂O) emissions were measured by the closed chamber technique from five plots along a transect in a nitrogen‐fertilised grassland, together with soil water content, soil temperature and water table depth, to investigate the effect of water table depth on N₂O emissions. N₂O fluxes varied from <1 g N₂O‐N ha^?1 day^?1 to peaks of around 500–1200 g N₂O‐N ha^?1 day^?1 after N fertiliser applications. There was no significant difference in overall average water table depth between four of the five plots, but significant short‐term temporal variations in water table depth did occur. Rises in the water table were accompanied by exponential increases in N₂O emissions, through the associated increases in the water‐filled pore space of the topsoil. Modelling predicted that if the water table could be managed such that it was kept to no less than 35 cm below the ground surface, fluxes during the growing season would be reduced by 50%, while lowering to 45 cm would reduce them by over 80%. The strong implication of these results is that draining grasslands, so that the water tables are only rarely nearer to the surface than 35 cm when N is available for denitrification, would substantially reduce N₂O emissions.     

营养液铵硝比对砂培韭菜生长及硝酸盐含量的影响

[目的]研究不同铵硝比营养液对韭菜生长及硝酸盐含量的影响。[方法]2008～2009年,对日光温室内砂培的2年生韭菜,分别浇施总氮量相同、铵硝比为0∶100,15∶85,30∶70,45∶55和60∶40的营养液。[结果]提高营养液铵硝比不仅大幅度降低了韭菜硝酸盐含量,而且显著地提高了春季韭菜的总产量。铵硝混合营养处理的韭菜硝酸盐含量极显著低于纯硝营养,铵硝比60∶40和45∶55处理的韭菜硝酸盐含量最低,均比纯硝营养降低了59.8%;铵硝比45∶55和30∶70处理的韭菜总产量显著高于纯硝营养,分别增产22.4%和14.0%。铵硝比对单茬韭菜产量的影响因收获时期不同而异,增铵对提高第1茬产量的作用最大、对第3茬无明显作用。[结论]45∶55和30∶70是适合韭菜砂培的营养液铵硝比。     

城市土壤重金属有机酸淋溶特征与动力学机制

以典型工业城陕西省铜川市土壤为研究对象,采用BCR(欧共体标准物质局)连续形态分级法和Hakanson潜在风险指数法分别研究了人类活动性元素Pb,Cu,Cr,Zn的形态分布特征、环境迁移与生态风险;利用振荡浸提动力学试验(25℃平衡振荡24h)探讨了人工合成低氨基多羧酸(APCAs)乙二胺四乙酸(EDTA)、二乙烯三胺五乙酸(DTPA)和低分子有机酸(LMWOAs)抗坏血酸(Vc)对重金属Pb,Cu,Cr,Zn的淋溶解吸特征与动力学机制。结果表明,铜川市工业区土壤重金属污染程度严重,总体潜在生态风险程度较强;重金属Zn和Cu的环境迁移趋势较大。淋溶动力学试验表明,不同类型有机酸对土壤Pb,Cr,Cu和Zn的淋溶解吸具有相似的动力学过程,但淋溶速率和解吸量随有机酸的不同各异。重金属Pb,Cr,Cu和Zn各形态量之和与有机酸EDTA和DTPA淋溶解吸量呈指数关系,而与低分子有机酸Vc淋溶解吸量成线性关系。从而进一步表明低分子有机酸Vc与氨基多羧酸类有机酸EDTA和DTPA对土壤重金属Pb,Cr,Cu,Zn淋溶解吸机制不同。     

长期不同施肥土壤中磷淋溶“阈值”研究

对长期 (2 4年 )不同施肥土壤中磷淋溶趋势的研究结果表明 :土壤耕层 Ca Cl2 - P和 Water- P的含量远比 Olsen- P要小得多 ,可以淋溶的磷素含量普遍较低 ;长期施用厩肥和化肥加秸秆并休闲的土壤更易发生磷素淋溶 ;Ca Cl2 - P和 Water- P之间以及 Water- P和 Olsen- P之间的相关系数均达到极显著水平 ;土壤耕层中 Olsen- P含量达 2 3mg/ kg,是该土壤发生磷素淋溶的“阈值”。