某化工污染场地土壤与地下水污染特征分析

以我国南方某典型化工污染场地为研究对象,通过场地调查确定了研究区的主要污染物为六六六、苯、氯苯和二氯丙烷,并进一步分析了污染物在土壤和地下水中的分布特征。污染物在土壤中浓度主要以生产车间为中心向四周逐渐减小,浓度梯度较大;在垂向上已穿透潜水层,浓度峰值出现在潜水层的中下部。污染物在潜水层中的分布呈现出和土壤中相似的特征,并表现出向南迁移的趋势。污染物在承压水层中的浓度峰值点与土壤和潜水重合,受区域地下水流向的控制,呈现明显向北迁移的趋势。由于地表较厚亚黏土的存在,增强了承压水的防污性能,污染物主要被截留于亚黏土中。     

土地处理过程中主要污染物对地下水污染的数学模拟方法讨论

本文通过对地下水水质数学模拟方法讨论,介绍了主要污染物在土地处理系统中的迁移转化过程概况,根据不同类型污染物特性,边界条件及污水排放形式,建立起相应的模型解析方程,并确定有关参数值,试图从量上来预测污染物浓度在地下水流中的时空变化规律。     

污染土壤的生态风险评估标准、方法和模型

本文介绍了生态风险评估的定义,国外在污染土壤生态风险评估领域的相关土壤标准、标准设置情况及其内容,生态风险评估的方法和步骤,土壤-有机污染物变化及迁移暴露模型、农药根区模型、土壤模型、土壤迁移及变化数据库和模型管理系统、农药径流对地表水的污染模型、多介质污染物变化、迁移和暴露模型等计算机模型及其理论基础。尤其是美国环保署在这一领域的系列工作及其思路,为国内在这方面的工作和研究提供一些参考。     

石油类污染物对土壤、地下水环境影响模拟分析

某油田利用千化池蒸发处理联合站排放的含油污水,部分干化池存在轻微渗漏,下渗的污水会对地下水产生污染。为掌握污染物在地下水中的迁移转化规律,建立含油废水的一维竖向迁移模型,并利用Hydrus-1D计算程序对地下水中污染物浓度随时间、运移距离衰减的情况进行模拟分析。分析结果对于控制干化池含油废水中石油类污染物对地下水环境的污染具有一定的参考价值。     

地下水中石油类污染物运移模拟研究＊

针对我国北方某油田的地下水特点,通过室内土柱模拟实验与数值模型模拟研究了石油类污染物随地下水运移的状况。模拟结果表明,地下水石油类污染物浓度随时间变化曲线总体上呈S型;污染前期地下水中污染物浓度增加较快,随着浓度的不断累积,后期浓度增加缓慢。计算结果显示,在50m处石油类污染物首次超过浓度限值的时间为586d,1000m处石油类污染物首次超过浓度限值的时间为12590d,污染过程表现出一定的滞后性。可见,吸附作用对石油类污染物迁移的影响很大,阻滞和延迟了污染物的迁移。     

页岩气开发场地地下水污染风险评价研究进展

页岩气勘探开发场地的潜在污染风险不同于普通场地，而针对页岩气开发全过程的场地土壤地下水污染风险评价研究较为薄弱。文章综述了污染场地风险评价的理论与方法，介绍了岩溶介质地下水及溶 质运移模拟的研究进展，指出由于页岩气开发场地的复杂性，基于污染物在土壤地下水系统迁移的过程模拟法（考虑岩溶通道）较适用于页岩气开发全过程污染风险评价，强调应加强页岩气开发不同生产阶段土壤、地下水 污染监测，拓展风险评价指标筛选的理论与方法。同时，应强化岩溶通道及裂隙相关参数的获取，并开展土壤-地下水耦合评价及页岩气开发全过程（勘探—钻井—压裂返排—生产）风险评价，为页岩气绿色开发提供理论指导。     

基于BIOSCREEN-AT模型的地下水污染事故预测分析

BIOSCREEN-AT作为地下水溶质迁移的解析解模型,将污染物的对流、弥散、吸附、衰减反应等作用采用数学方法表示,操作简单明了,使用方便,国际上应用广泛。在对BIOSCREEN-AT模型的原理及参数分析基础上,以某城市生活垃圾填埋场渗滤液渗漏情景为例,运用该模型对地下水中典型污染物COD_(Mn)的浓度分布曲线及污染羽形态进行描述。通过模型参数率定及模型预测,为地下水监测方案及地下水环境保护措施的制定提供理论依据。     

土壤的净化功能在污水处理中的作用

本文根据土壤的净化机制,分别对主要污染物在土壤中的转化过程进行了分析,以了解不同条件下土壤对污染物的净化效果及对地下水的影响。探讨了土壤的净化功能在污水处理中的作用,力求进一步解决我国城市污水土地处理与利用问题。     

油田开发对地下水水源地的影响及对策分析

分析了在油田开发工程可能对水源地产生影响的三类事故,筛选出风险最大的事故是注水井井壁泄漏事故。采用地下水中污染物三维迁移转化模型和MODFLOW、MT3D模拟计算软件对某地下水水源地可能受到的石油类污染进行数学模拟,并针对模拟结果提出了污染预防和控制措施。     

典型铬污染场地污染状况研究

为研究典型工业污染场地污染特点,选取某一化工厂铬污染场地作为研究对象,在厂区内不同功能区采集了土壤和地下水样品。对样品进行前处理后,通过分光光度法对样品中的Cr(Ⅵ)进行了测定。结果显示,该化工厂铬渣堆积及铬盐生产等区域存在很严重的土壤和地下水污染,地下水属于Ⅴ类水质;污染物在土壤和地下水中纵向迁移扩散严重,在土壤中污染深度达到了12 m;污染程度随离污染核心区的距离增大而逐渐减小。     

The “Short Cut” Approach for the Reality of Enhanced Groundwater Contamination

Based on the reality of (a) soil heterogeneity in the vadose zone, (b) enhanced desorption from soil and solubility in water of water insoluble contaminants in the presence of surfactants, and (c) wetting/drying cycles of groundwater recharge (a major cause of fractures formation), a coherent “short-cut” conceptual approach is advanced to account for enhanced groundwater contamination. This is an attempt to close the gap between theory, lab simulations and conventional modelling-based predictions, and observed higher concentrations and more rapid arrival times of contaminants reaching groundwater. Recent data concerning chloride ion and non-ionic surfactants concentrations in aquifers and groundwater wells, combined with previous results concerning the concentrations of tritium, chlorides, metals, organic hydrocarbons and surfactants in the unsaturated and saturated zones of Israel's aquifers, are accounted for in terms of the “short-cut” approach. The contradiction between predictions of groundwater contamination made with conventional, deterministic, homogeneous models and the actual observed behavior of contaminants in soils and aquifers is thus explaind. The “short cut” approach should not be perceived as a better type of model to guide modelling. Rather, it is a proposal for a conceptual change from the realistically invalid, but commonly accepted, conventional “buffer-protective soil/long-term groundwater contamination” to the “short cut” conceptual model to explain the enhanced groundwater contamination actually observed. Although the validity of the proposed approach is strongly supported by the data here presented for the case of Israel (serving as an illustrative case study), selected results and conclusions drawn from studies conducted worldwide suggest its general applicability and usefulness. A major conclusion evolved from the “short-cut” conceptual model is that contemporary groundwater management policies, based on the current perception of groundwater contamination processes and their modelling, may result in an irreversible detrimental effect on the environmental situation in the long run. In any case, prevention, rather than correction/remediation, is strongly recommended as the strategy of choice for rational long-term management of groundwater resources.     

石油类污染物在土壤中的环境行为

土壤中石油类污染物的环境行为一直是环保界研究的重点。为此,简述了土壤中石油类污染物的来源、危害及存在状态,介绍了其在土壤中的迁移、吸附和降解行为,以及其行为特征和影响因素。全面了解土壤中石油类污染物的环境行为,对保护生态环境、推动石油工业的持续发展具有重要意义。     

Long-term performance of a land treatment facility for the bioremediation of non-volatile oily wastes

The current study reports on operational and performance aspects of a land treatment facility for managing oily wastes generated from heavy vehicle maintenance over a 5-year period. Samples of soil and groundwater from the land treatment plots were analyzed for a range of contaminants and microorganisms over this period. The soil analyses indicated that the process has been operating efficiently even at high wastewater loadings with maximum degradation rates of 250 mg/kg per day (year 1) and average rates of 10–35 mg/kg per day (years 2–5). Hydrocarbon degraders comprised more than 80% of the total (measured) soil heterotrophic population and were present at 10⁶–10⁸ (per gram soil) once the process was optimized. The facility was capable of treating 140 kl of oily wastewater per day (average petroleum hydrocarbon content of 2% w/v) over the entire period. During this time there was no evidence of accumulation of any major metals or polycyclic aromatic hydrocarbon (PAH) compounds in the soil. Groundwater sampling and analysis indicated that the land treatment facility was not leading to contamination of any groundwater taken from bores in the vicinity of the facility. The land treatment process continues to be effective for treatment of non-volatile waste oils at this remote and high evaporation (arid) site.     

Adsorption and degradation of triazophos, chlorpyrifos and their main hydrolytic metabolites in paddy soil from Chaohu Lake, China

Triazophos and chlorpyrifos are organophosphorus pesticides (OPs), and their primary hydrolytic metabolites are 1-phenyl-3-hydroxy-1,2,4-triazole (BZC) and 3,5,6-trichloro-2-pyridinol (TCP). In this study, the adsorption and degradation of triazophos, chlorpyrifos, BZC and TCP were investigated in paddy soil from Chaohu Lake, China. Adsorption tests demonstrated that the adsorption of these compounds to soils could be described by the Freundlich equation. Moreover, chlorpyrifos displayed the highest affinity for adsorption, followed by triazophos, BZC and TCP. Degradation of these compounds in non-sterile soil followed first-order exponential decay kinetics, and the half-life (t(1/2)) of these contaminants ranged from 8.40 to 44.34 d. Sterilization of soil decreased the degradation rate, indicating that microorganisms played a significant role in the degradation of these compounds. The values of t(1/2) and K(oc) were fitted to obtain models that could predict the leaching potential of the contaminants from soil. Compared to their parent compounds, BZC and TCP showed high potential for leaching into groundwater. The inoculation of OPs-degrading bacterium (Diaphorobacter sp. GS-1) removed 95.38%, 100% and 100% of triazophos, chlorpyrifos and BZC in paddy soil after 21 d, respectively. The pollution risk of triazophos, chlorpyrifos and BZC could be greatly decreased by inoculating soil with Diaphorobacter sp. GS-1, which decreases the t(1/2) of the contaminants.     

Phytoremediation of aged petroleum sludge: effect of irrigation techniques and scheduling

The use of higher plants to accelerate the remediation of petroleum contaminants in soil is limited by, among other factors, rooting depth and the delivery of nutrients to the microsites at which remediation occurs. The objective of this study was to test methods of enhancing root growth and remediation in the subsurface of a contaminated petroleum sludge. The phytoremediation of highly contaminated petroleum sludge (total petroleum hydrocarbons >35 g kg(-1) was tested in the greenhouse as a function of the frequency and the depth of irrigation and fertilization. Water and dissolved plant nutrients were added to the soil surface or at a depth of 30 cm, either daily or weekly. Equivalent quantities of water and nutrients were added in all cases. Daily irrigation at a depth of 30 cm invoked greater root growth and enhanced contaminant degradation relative to all other treatments. In the absence of plants, residual concentrations of petroleum hydrocarbons after 7 mo were higher than with plants. The presence of plant roots clearly improved the physical structure of the soil and increased microbial populations. Thus, the plant roots in conjunction with daily additions of soluble N and P appeared to enhance oxygen transport to greater depths in the soil, stimulate petroleum-degrading microorganisms, and provide microbial access to soil micropores. Subsurface irrigation with frequent, small amounts of water and nutrients could significantly accelerate phytoremediation of field soils contaminated with petroleum hydrocarbons.     

油污土壤生物修复实验研究

为了有效预防和治理因石油开采、运输等造成的土壤污染,对大庆地区油污土壤进行了生物修复的实验研究,通过室内盆栽模拟实验,对芦苇和香蒲根际土壤的石油类污染物总含量、石油烃类组分浓度、非烃组分浓度进行了测定。结果表明,芦苇和香蒲对石油类污染物具有比较明显的降解作用,可以使被污染土壤中的某些油污成分逐渐被选择性消耗。实验还可看出,芦苇和香蒲对石油类污染物中正构烷烃的降解能力高于非正构烃。总体看,芦苇对石油类污染物的降解能力强于香蒲,但芦苇对非正构烃的降解能力略逊于香蒲。     

土壤对石化工业废水的吸咐试验分析

通过土壤对石化工业废水的吸附试验分析，可以预测工程废水对地下水的影响情况，对保护当地地下水水质，指导工程环境建设具有十分积极的作用     

Comparison of models of simazine transport and fate in the subsurface environment in a citrus farm

Contamination of groundwater by agrochemicals is now widely recognized as an extremely important environmental problem. Modern agricultural practices involve the combined use of irrigation with the application of large amounts of agrochemicals to maximize crop yield. Due to flood irrigation and natural runoff, agricultural activities might generate soil, surface water and groundwater contamination problems and leaching of pesticides. Modeling of the transport and fate of pesticides, such as simazine, may help understand the long-term potential risk to the subsurface environment. This paper illustrates a comparative study via the use of three different pesticide transport simulation models and the applicability of those models in determining the groundwater vulnerability to pesticides contamination in a citrus orchard located at the Lower Rio Grande Valley (LRGV). The three models used in the study are the pesticide root zone model-3 (PRZM-3), the pesticide analytical model (PESTAN) and integrated pesticide transport modeling (IPTM). The concentration values obtained from all three models are in agreement, and they show a decreasing trend from the surface through the vadose zone. The problem is how to use this information and, specifically, how to combine the testimony of a number of experts into a single useful judgment. With the aid of the fuzzy multiattribute decision making method, PRZM-3 is deemed as the most promising one for such precision farming applications.     

Tool for assessment of process importance at the groundwater/surface water interface

The groundwater/surface water interface (GWSWI) represents an important transition zone between groundwater and surface water environments that potentially changes the nature and flux of contaminants exchanged between the two systems. Identifying dominant and rate-limiting contaminant transformation processes is critically important for estimating contaminant fluxes and compositional changes across the GWSWI. A new, user-friendly, spreadsheet- and Visual Basic-based analytical screening tool that assists in evaluating the dominance of controlling kinetic processes across the GWSWI is presented. Based on contaminant properties, first-order processes that may play a significant role in solute transport/transformation are evaluated in terms of a ratio of process importance (P_i) that relates the process rate to the rate of fluid transfer. Besides possessing several useful compilations of contaminant and process data, the screening tool also includes 1-D analytical models that assist users in evaluating contaminant transport across the GWSWI. The tool currently applies to 29 organics and 10 inorganics of interest within the context of the GWSWI. Application of the new screening tool is demonstrated through an evaluation of natural attenuation at a site with trichloroethylene and 1,1,2,2-tetrachloroethane contaminated groundwater discharging into wetlands.