氮钾配施对大蒜增产效应的研究

1999～2001年连续三年多点试验结果表明:在安徽省来安县大蒜产区水稻土上氮钾配施对大蒜产量及品质都有明显的正效应,蒜苔增产24.2%～29.2%,蒜头增产17.3%～18.9%。氮钾肥的产量效应与土壤的氮钾水平和氮钾比例密切相关。氮肥的适宜用量为N300～375kg/hm2,钾肥为K2O150kg/hm2。回归方程计算显示,大蒜产区的土壤临界钾素含量为101μg/ml,氮素临界含量为46μg/ml(ASI法测定)。氮钾配施并能提高蒜苗、蒜苔维生素C及可溶性糖含量。增施钾肥对大蒜的经济效益明显提高,产投比为11.07～13.26。     

Using the soil gas radon as an indicator for ground contamination by non-aqueous phase-liquids

1 The Problem  One of the major problems facing risk assessment at polluted industrial sites and military bases is subsurface contamination by non-aqueous phase-liquids (NAPLs), since tracing the extent of a NAPL plume using conventional methods (drive point profiling) is usually associated with difficulties. In an effort to trace subsurface contamination as precisely as possible, monitoring points are placed in the area that might be affected by contaminants, and groundwater and soil samples are taken to the laboratory for analysis. However, the final number of monitoring points is hardly ever sufficient for distinctive contamination mapping, and this may ultimately result in an unsuitable remediation action being taken. 2 Objectives  To obtain a more detailed image of a subsurface NAPL plume and, hence, to facilitate remediation measures that are best suited for the site in question, a denser network of monitoring points is desirable. The aim of the investigation described in this paper was therefore to develop a new detection method for subsurface NAPL contamination, which is based on an easily accessibleindicator for NAPLs rather than on the analysis of soil and groundwater samples taken at the site. Based on the good solubility of radon in NAPLs, the idea was put forward that subsurface NAPL contamination should have an influence on the natural radon concentration of the soil gas. Provided this effect is significant, it would be possible to carry out a straightforward radon survey on an appropriate sampling grid covering the suspected site and thus enabling the NAPL contamination to be detected by the localization of anomalous low radon concentrations in the soil. The overall aim of the investigation was to assess the general suitability of the soil-gas radon concentration as an indirect tracer for NAPL contamination in the ground. 3 Methods  The partitioning coefficient K_NAPL/air is one of the most influential parameters governing the decrease of the radon concentration in the soil gas in the presence of a subsurface NAPL contamination. Since NAPL mixtures such as gasoline, diesel fuel and paraffin are among the most important NAPLs regarding remediation activities, laboratory experiments were performed to determine the radon-partitioning coefficient for these three NAPL mixtures. Field experiments were carried out as well. The aim of the field experiments was to test the use of the soil-gas radon concentration as a tracer for NAPL contamination on-site. For the field experiments, each site was covered with a suitable grid of soil gas sampling points. Finally, the lateral radon distribution pattern achieved on each of the sites was compared to the respective findings of the earlier research performed by conventional means. 4 Results and Discussion  The results of the laboratory experiments clearly show a very strong affinity of radon to the NAPL mixtures examined. The partitioning coefficients achieved correspond to those published for pure NAPLs (Clever 1979) and are thus in the expected range. The results of the field experiments showed that the minimum radon concentrations detected match the respective NAPL plumes traced previously. 5 Conclusions  Both the results of the lab experiments and the on-site findings demonstrate that the soil-gas radon concentration can be used as an indicator for subsurface NAPL contamination. The investigation showed that NAPL-contaminated soil volumes give rise to anomalous low soil-gas radon concentrations in the close vicinity of the contamination. The reason for this decrease in the soil-gas radon concentration is the good solubility of radon in NAPLs, which enables the NAPLs to accumulate and ‘trap’ part of the radon available in the soil pores. 6 Recommendations and Outlook  Further research is required into contamination with rather volatile NAPLs such as BTEX. Further research is also needed to examine whether it is possible to not only localize a NAPL plume, but also to obtain some quantitative information about the subsurface NAPL contamination. The authors also believe that additional investigations should be carried out to study the ability of the method to not just localize a NAPL contamination, but also to monitor on-site, clean-up measures.     

固定化微生物技术及其在污染土壤修复中的应用

固定化微生物技术是一种新的生物处理技术,与普通生物处理法相比有许多优点.本文对固定化微生物的制备方法、固定化微生物的载体、固定化微生物的反应特性以及固定化微生物技术在污染土壤治理中的应用和研究进展状况进行了综述,并对其今后的发展方向作了探讨.     

多氯联苯复合污染土壤的土著微生物修复强化措施研究

通过室内模拟试验,以不同C源、C/N比、水分及通透性为调控因子,对多氯联苯(PCBs)长期复合污染土壤的土著微生物强化修复进行了初步研究。结果表明,PCBs长期复合污染土壤中,在土壤水分含量为田间持水量的60%时,加入淀粉、葡萄糖和琥珀酸钠均在一定程度上增加了细菌和真菌数量,从而促进土壤中PCBs的土著微生物降解。不同种类的C源对PCBs污染土壤的土著微生物降解效果存在明显差异,且其降解效果与C源的施用剂量密切相关。当淀粉加入量为C1.0g/kg土时,土壤中PCBs的降解效果较好,而葡萄糖和琥珀酸钠加入量为C0.2g/kg土时,PCBs的降解效果明显。土壤C/N比为10:1的处理效果优于C/N比为25:1和40:1。土壤人为翻动有利于PCBs污染土壤中细菌和真菌的生长,提高土著微生物的代谢活性,从而促进土壤中PCBs的自然降解。这为进一步探讨加速土壤中PCBs降解的最适条件和研发POPs污染土壤的生物修复技术提供了科学依据。     

土壤修复-新兴的土壤科学分支学科

本文在回顾国内外土壤修复研究与发展概况的基础上,首次提出土壤修复是一门新兴的土壤科学分支学科,全面系统地论述了我国土壤修复学科的研究任务和战略定位,并针对新形势下所面临的挑战与机遇,探讨了近期土壤修复学科研究的重要方向与科学问题。     

不同施肥制度下褐土结合态腐殖质动态变化

通过8年定位试验,研究了不同施肥制度下褐土结合态腐殖质动态变化规律。结果表明,不同施肥制度主要影响松结态腐殖质碳含量,对稳结态和紧结态的影响较小。采用有机肥(物)料配施常量NPK化肥,土壤有机碳和结合态腐殖质碳表现为以递减速率持续上升;不施肥和单施常量NPK化肥则造成土壤有机碳和结合态腐殖质碳不断降低,其下降速率亦表现为递减。在试验的不同阶段,土壤有机碳的亏损或盈余向结合态腐殖质碳分配比例的变化态势各异,不施肥处理随时间的延长渐增,而施用有机肥(物)料配施化肥则呈相反趋势。     

基于Fluent的组合气吸式排种器关键部件仿真研究

以棉花小区播种机排种器为研究对象,采用模拟仿真试验技术研究组合气吸式排种器排种过程,在排种器的吸气口截面设置不同的边界条件（包括压强和气流速度）,在开放条件下分析导向槽盘上导向槽的速度场和压力场。结果表明,距导向槽盘中心越远的位置,其气流速度和压强越小。设置排种器吸气口界面的边界条件相同,针对气吸盘和导向槽盘组合后形成的气吸孔开展气流场仿真分析。入口处气流压强300 Pa、速度21.97 m/s,此时气吸孔气流场压强2 481.8 Pa、气流速度61.67 m/s,该仿真结果与试验所测得的结果基本一致。试验验证并确定排种器几何参数、动力参数对气流场的变化和影响规律,可为设计试制播种机提供参考。     

井渠结合灌区水资源多目标优化配置模型与应用

将灌区的经济效益和生态环境效益结合在一起综合考虑,在灌区水资源配置时不仅只追求获得最大经济效益,同时尽量将地下水位控制在适宜范围内,以维持地下水资源的采补平衡,实现水资源的可持续利用。按此原则,建立了井渠结合灌区水资源多目标优化配置模型。实例计算表明：应用此模型指导井渠结合灌区的水资源配置可实现真正意义上的地表水和地下水联合运用,提高水资源利用效率。     

硅对水稻生长的影响及其缓解镉毒害机理研究进展

为研发高效硅肥和防治农田镉污染提供借鉴资料,本文综述了施加硅肥对水稻生长发育的影响,包括提高水稻产量和品质,增强抗倒伏、抗病虫害及干旱等逆境的能力,尤其是增强抗镉毒害等能力。并从生理学机制和土壤学机制两方面重点分析了施加硅肥对缓解镉毒害作用的可能机理。生理学机制方面：硅通过参与水稻的生理代谢活动,使水稻抗氧化系统酶的活性和清除自由基的能力增强;抑制镉的吸收及其在水稻体内的运输;硅与镉在水稻体内的螯合和区隔作用。土壤学机制方面：硅肥改变土壤理化性质,降低土壤中有效态镉的含量;硅镉吸附沉淀作用,减少水稻对镉吸收。最后针对硅肥的开发利用及技术推广提出展望。     

土壤重金属钝化效果评估——基于大田试验的研究

采用野外大田试验,研究了钙镁磷肥(Calcium-magnesia phosphate fertilizer)、麦饭石(Medical stone)、氧化铁吸附剂(Ferric oxide adsorbent)、氧化铝复合材料(Alumina composite)、植物型有机肥(Plant-based organic fertilizer)、牛粪(Cow dung)、骨炭(Bone char)对某地重金属污染农田的钝化修复效果,并利用动态加权评估方法评估了这几种钝化材料的综合适用性。试验结果表明:几种材料对土壤pH影响均较小,钙镁磷肥、麦饭石微量提高了土壤pH,与对照组相比分别增加0.68和0.74个单位;施加植物型有机肥、牛粪和骨炭提高了土壤有机质含量,与对照组相比分别增加了3.19、2.64 g·kg~(-1)和1.17 g·kg~(-1)(10.04%、8.31%和3.68%)。几种材料在0.6%的投加量下,除植物型有机肥外均有较好钝化效果,土壤有效态镉降低18%以上,且显著减少糙米中镉蓄积量(0.062～0.087mg·kg~(-1)),低于国家食品安全标准限值。为综合评估几种材料的效果及适用性,以土壤重金属有效态含量、糙米镉含量、修复成本和产量为指标构建动态加权函数综合评估模型,评估结果表明,钙镁磷肥的综合修复效果最好,其次为骨炭和植物型有机肥。