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1.
过硫酸盐已经被广泛用于土壤和地下水有机污染物的原位化学氧化修复。随着乙醇汽油的推广,乙醇汽油引起的地下水污染问题越来越严重,因此有必要去除该类污染物。前人研究乙醇汽油污染修复多数停留在自然修复技术,为了进一步探究去除地下水中乙醇汽油更为有效的技术手段,深入了解乙醇对降解苯系物(BTEX)存在的潜在风险,需要研究使用新的修复方法。文章通过批实验探索了过硫酸盐氧化法对乙醇汽油污染地下水的修复效果,以及Fe2+活化和过硫酸盐添加方式变化对乙醇汽油中苯系物(BTEX)和乙醇的去除影响。结果表明:活化后的过硫酸盐能够有效去除地下水中的BTEX,但会抑制BTEX的生物降解作用;当有乙醇存在时,过硫酸盐能够优先氧化BTEX,其去除速率明显高于乙醇,这与单纯生物降解作用相反。在过硫酸盐投注总量一定时,分批添加更有利于BTEX的去除,但对乙醇去除没有明显促进作用。该研究为过硫酸盐原位化学氧化技术在地下水乙醇汽油污染修复中的应用提供了重要参考。 相似文献
2.
汽油污染含水层中芳香烃的自然去除与生物降解特征 总被引:7,自引:0,他引:7
石油烃污染地下水是一个普遍而严重的环境问题.用砂卵石、中粗砂、细砂、粉砂和粘土等在实验室内按照自然界沉积物层序制作了一个含水层物理模型,具有给水、排水、监测、抽提、淋滤与注入等功能.利用该模型开展石油烃污染地下水的特征研究结果表明,苯、甲苯、乙苯和二甲苯(benzene,toluene,ethylbenzene,xylene;BTEX)各溶解组分能够被自然去除,其中甲苯自然衰减的速率系数为0.057 5~0.150 4 d-1,二甲苯为0.068 3~0.104 6 d,乙苯大约为0.047 8 d,苯为O.017 8~0.040 6 d.甲苯与二甲苯容易被去除,然而苯的去除则需要较长的时间.作为BTEX去除反应的电子受体,溶解氧、硝酸盐在需氧或厌氧条件下具有优先利用的机会,而硫酸盐则缺乏优先利用的机会.BTEX溶解组分浓度的降低,加上电子受体浓度的降低,可以表明含水层存在需氧条件与硝酸盐还原条件下的内在生物降解作用.其意义在于通过增加含水层中电子受体的浓度,将有助于内在生物降解能力的增强,从而能够提高含水层中污染物去除的效果. 相似文献
3.
监测自然衰减技术(MNA)是修复地下水土有机污染最经济和有效的方法之一。在自然衰减的评价中,美国主要是从3个方面的证据来揭示自然衰减的发生:污染物质量减少;表征生物降解的地球化学指标的变化;通过微生物降解菌研究为生物降解提供直接证据。本文总结了目前国际上获取自然衰减证据的主要方法:污染物浓度变化趋势统计法、污染物质量守恒和质量通量分析法、溶质运移的解析模型、溶质运移的数值模型、地球化学证据方法、稳定同位素方法和微生物菌群研究等方法。我国在自然衰减评价方面的研究较少。由于自然衰减修复时间较长、修复效率较低,在实际应用中,联合运用强化衰减修复技术和MNA技术成为地下水土治理的主要发展趋势。 相似文献
4.
监测自然衰减(monitoring natural attenuation,MNA)技术是目前普遍认可的去除地下水中挥发性有机污染物(volatile organic compounds,VOCs)的技术。但受其修复周期长、监测费用昂贵等因素的影响,实地开展MNA技术修复污染场地具有一定的局限性。基于此,本研究运用多相流数值模拟手段识别了某石油污染场地内典型VOCs污染物(苯、甲苯、萘)在地下水中的自然衰减过程并评估了其自然衰减能力。结果表明:采用TMVOC所建立的多相流数值模拟模型能较好地预测和识别VOCs在地下水中的衰减规律;在研究区中,苯、甲苯和萘由于理化性质差异,在地下水中的污染羽分布特征不同,其自然衰减过程受挥发、吸附和生物降解作用的影响程度也不同;挥发和生物降解作用对VOCs自然衰减的影响程度均为苯>甲苯>萘,而吸附作用对VOCs自然衰减的影响程度为萘>甲苯>苯;在污染源被阻断的前提下,苯、甲苯和萘分别在泄漏发生7.0、6.5和6.0年后通过自然衰减达到理想去除效果。本文研究成果可以为水文地质条件类似的VOCs污染场地MNA修复方案的制定和修复效果评估提供理论支撑。 相似文献
5.
监测式自然衰减(MNA)能够高效低耗地原位修复石油污染地下水的场地,微生物对污染物的降解对MNA过程起到了重要作用。在分析东北石油污染场地地下水中总石油烃(TPH)、电子受体的质量浓度分布和变化规律基础上,划分了微生物功能区。采用溶质通量计算法,对MNA原位修复的潜能及其微生物降解效果进行了评估。结果显示,场地微生物降解正在发生,利用的电子受体不同,划分为Mn、Fe和SO2-4还原区。污染通量模型计算显示:上游地区微生物降解强度不断增强,下游地区微生物降解强度不断降低。监测期内石油烃总量降低了394 kg,微生物降解为自然衰减过程中的主要作用,其贡献率为64%~93%,每个通量断面内微生物降解率为0.18~0.73 kg/d。由此可以证明,MNA可以有效地修复地下水中的石油污染。 相似文献
6.
石油类污染场地的自然衰减作用 总被引:1,自引:0,他引:1
在野外石油类污染场地地质、水文地质调查的基础上,对场地地下水中总石油烃的吸附、生物降解等自然衰减作用进行研究。开展了砂质粉土、粉砂、细砂等场地包气带、含水层介质对总石油烃的吸附动力学实验、等温吸附实验、不同矿化度吸附实验、生物降解实验和挥发实验等。实验结果显示,砂质粉土、粉砂、细砂的吸附平衡时间分别为4、7和10 h;通过计算确定了每种介质对总石油烃的等温吸附模型。矿化度对介质吸附总石油烃能力的影响表现为,矿化度越高吸附量越高。生物降解实验结果表明,在场地水土条件下,降解能力最强,且降解符合一级衰减动力学方程。研究表明,地下水受到污染后,吸附、降解、挥发等自然衰减作用对地下水石油类污染物的去除具有非常重要的作用。 相似文献
7.
岩溶含水系统遭受石油烃污染的环境问题十分普遍。相对于多孔含水介质,石油烃BTEX在石灰岩含水介质中的生
物可降解性还不确定。为此,本研究开展了BTEX在石灰石和岩溶地下水介质中的静态微元体实验。经过77天的实验检测
分析,结果表明:(1) BTEX化合物在可利用电子受体溶解氧或硝酸盐存在条件下具有生物可降解性;(2) 向系统中补充
电子受体硝酸盐,具有促进生物降解的作用,其对BTEX的去除率可高达94%;(3) 未发现补充硫酸盐能够促进BTEX生物
可降解性;(4) 甲苯和二甲苯容易被生物降解,但苯的去除具有一定的难度。 相似文献
8.
浅层地下水氯代烃污染天然衰减速率的估算 总被引:1,自引:0,他引:1
天然衰减恢复技术是恢复和控制浅层地下水氯代烃污染的技术之一,如何简便获取可靠的氯代烃衰减速率常数是该技术应用的一个关键。趋势线分析方法是一种简便有效的方法,在污染羽状体稳定的条件下,通过地下水流向上至少3口监测井的资料,能够比较准确地估算出污染物的天然衰减速率常数和生物降解速率常数。某氯代烃污染典型区的应用实例研究表明,该区四氯乙烯(PCE)的天然衰减速率常数和生物降解速率常数分别为0·000925d-1和0·000537d-1,证实该区浅层地下水中的PCE存在天然生物降解,但降解速率比较缓慢。忽略吸附作用的天然衰减容量计算所得出的天然衰减速率常数明显小于实际结果,说明尽管典型区包气带及含水层介质的有机碳含量很少,但它们对PCE的吸附作用不容忽视。 相似文献
9.
石油类有机物污染是地下水环境领域亟须解决的关键课题.本次研究耦合数值模拟和水文地球化学技术模拟岩溶裂隙含水层中石油类有机物的自然衰减过程并定量计算其自然衰减机制.基于BIOSCREEN模型的模拟计算可知,近30年对流、弥散、稀释等物理过程和生物降解过程对石油类有机物衰减贡献率的平均值分别为31.53%和68.47%,生物降解作用是岩溶裂隙含水层自然修复能力的主要机制.利用质量守恒定律分析水化学(HCO3-、NO3-)和同位素(δ15NNO3、δ18ONO3和δ13CDIC)之间的相关关系可知石油类有机物生物降解贡献地下水HCO3-的平均值为33.93%;石油类有机物生物降解消耗主要电子受体NO3-贡献地下水δ13CDIC的百分率为30.77%且其占总生物降解的90.69%. 相似文献
10.
生物曝气技术对石油类污染地下水的修复效果及去除机制 总被引:1,自引:0,他引:1
针对东北某石油污染场地水文地质条件进行模拟,按照试验场地地层现状进行实验室缩放,研究微生物在含水层介质为砾砂、粗砂和中砂中的迁移速度以及含水层介质吸附的微生物量。选取苯和二甲苯作为目标石油污染物,研究生物曝气技术对被污染地下水的修复效果及其去除污染物的机制。实验结果表明:微生物在介质中的迁移速度从大到小为砾砂、粗砂、中砂;介质吸附微生物量的顺序从大到小为中砂、粗砂、砾砂;生物曝气4个月后,苯和二甲苯去除率分别为86.4%和81.7%,BS对中砂层中的苯和二甲苯去除效果好于砾砂层和粗砂层,苯的去除效果好于二甲苯。由挥发机制去除的污染物为46.24%,生物降解去除的污染物为36.98%,BS技术可以有效去除地下水中石油类污染物。 相似文献
11.
Field investigation of the natural attenuation and intrinsic biodegradation rates at an underground storage tank site 总被引:1,自引:0,他引:1
Contamination of groundwater by petroleum-hydrocarbons is a widespread environmental problem. Natural attenuation is a passive
remedial approach to degrade and dissipate contaminants in soil and groundwater. In this study, a mass flux approach was used
to calculate the contaminant mass reduction and field-scale decay rate at a gasoline spill site. The mass flux technique is
accomplished using the differences in total contaminant mass flux across two cross sections of the contaminant plume. The
mass flux calculation shows that up to 88% of the dissolved BTEX (benzene, toluene, ethylbenzene, and xylene isomers) removal
was observed by natural attenuation processes. The efficiency of intrinsic biodegradation was evaluated by the in situ tracer
method. A first-order decay model was applied for the natural attenuation and intrinsic biodegradation rate calculation. Results
reveal that intrinsic biodegradation process was the major cause of the BTEX reduction among the natural attenuation mechanisms,
and iron reduction was the dominant biodegradation pattern within the plume. Approximately 87% of the BTEX removal was caused
by intrinsic biodegradation processes. The calculated BTEX natural attenuation and intrinsic biodegradation rates were 0.24
and 0.16% l/day, respectively. Results suggest that natural attenuation mechanisms can effectively contain the plume, and
the mass flux method is useful in assessing the efficiency of the natural attenuation.
Received: 6 December 1999 · Accepted: 11 July 2000 相似文献
12.
Trimethylbenzene (TMB), as a constituent of gasoline, is often expected to be used as a conservative tracer in anaerobic BTEX-contaminated
groundwater site to correct for attenuation due to dispersion, dilution and sorption along a flow path. To evaluate the suitability
of using TMB as a tracer and to better understand biodegradability of TMB in contaminated groundwater by gasoline under anaerobic
conditions, laboratory microcosms were conducted with mixed nitrate/iron/sulfate electron-acceptor amendments, using aquifer
materials collected from Canadian Forces Base (CFB), Borden, Ontario, Canada. The results showed that under denitrifying conditions,
biodegradation of 1,3,5-TMB, 1,2,4-TMB and 1,2,3-TMB were relatively slow and after 204 days of incubation approximately 27,
24, and 16% of the initial concentrations, respectively, were degraded in the microcosms. Under sulfate-reducing conditions,
TMB isomers were recalcitrant. In contrast, significant biodegradation of TMB was observed under iron-reducing conditions.
1,3,5-TMB, 1,2,4-TMB and 1,2,3-TMB were degraded to 44, 47, and 24% of initial concentrations with first-order biodegradation
rate constants of 0.003, 0.006 and 0.013 d−1, respectively. This study indicates that TMB biodegradation is insignificant under nitrate and sulfate-reducing conditions
but significant under iron-reducing conditions. Therefore, the use of TMB as a tracer for interpreting removal of other biodegradable
gasoline constituents such as BTEX requires caution, especially in the presence of iron-reducing conditions. 相似文献
13.
Monitored natural attenuation can be a viable option for remediation of groundwater contamination by BTEX compounds. Under
the field conditions, the rate of contaminant mass attenuation through natural processes, such as biodegradation, to a large
extent affected by the groundwater flow regime, which is primarily controlled by the aquifer heterogeneity. Numerical simulation
techniques were used to describe quantitatively the relationship between biodegradation rate of BTEX and aquifer heterogeneity.
Different levels of aquifer heterogeneity were described by random hydraulic conductivity fields (K) having different statistical
parameters, the coefficient of variation (CV) and the correlation length (h). The Turning Bands Algorithm was used to generate
such K fields. Visual MODFLOW/RT3D was used to simulate the fate and transport of dissolved BTEX plume within heterogeneous
aquifers. The multispecies reactive transport approach described BTEX degradation using multiple terminal electron-accepting
processes. First-order biodegradation rate constants were calculated from simulated BTEX plumes in heterogeneous flow fields.
The results showed that aquifer heterogeneity significantly affected biodegradation rate; it decreased with increasing CV
when h was in the range of up to 12 m, whereas it increased with increasing CV when h was greater than about 12 m. For well characterized aquifers, this finding could be of great value in assessing the effectiveness
of natural attenuation during feasibility studies at BTEX contaminated sites. 相似文献
14.
反硝化增强去除乙醇对多孔介质渗透性的影响 总被引:1,自引:0,他引:1
随着乙醇混合汽油的不断推广应用,乙醇将成为地下水中与苯、甲苯、乙苯及二甲苯的同分异构体(BTEX)共存的一种新型污染物。通过4 个含水砂柱实验,研究了乙醇存在及其强化去除对含水介质渗透性能的影响。结果表明:在有限溶解氧与反硝化增强修复条件下,乙醇去除率达92% 以上;生物过程对介质渗透能力影响程度随乙醇初始浓度、消耗速率与补充频率而变化:乙醇初始浓度接近1 000 mg/L 和3 000 mg/L 时,乙醇消耗快,补充频率高,渗透系数下降总体上有连续性,最大下降幅度达一个数量级(×10-1 cm/s);乙醇初始浓度达到5 000 mg/L 时,渗透性下降显著,可下降两个数量级,但乙酸的积累可影响生物活性,并使得渗透性变化出现反复;当不含乙醇时,汽油溶解组分对介质渗透性能的影响相对不明显。 相似文献
15.
污染河流中苯系物对浅层地下水影响的室内模拟试验 总被引:1,自引:0,他引:1
为了研究污染河流中苯系物对浅层地下水的影响,室内试验选用3种天然砂土作为渗透介质,以生活污水模拟污染河流,68d以后发现,苯、甲苯和苯系物总量的总去除率在粗砂中分别为32.06%、21.39%和27.13%。在两种中砂中总去除率2号柱为76.26%、81.40%和87.99%,3号柱为68.94%、74.41%和81.69%,粗砂小于中砂,并且由于2号柱的粘粒物质含量大,其总去除率大于3号柱和1号柱。苯系物各组分浓度随深度呈递减趋势,苯系物的净化作用主要发生在地表以下0.4m范围内。水动力特征的改变影响污染物的迁移和转化特征,苯系物的去除机理为挥发、吸附和生物降解,其中最主要的是厌氧条件下的微生物降解。 相似文献
16.
An oil-refining plant site located in southern Taiwan has been identified as a petroleum-hydrocarbon [mainly methyl tert-butyl ether (MTBE) and benzene, toluene, ethylbenzene, and xylenes (BTEX)] spill site. In this study, groundwater samples collected from the site were analyzed to assess the occurrence of intrinsic MTBE biodegradation. Microcosm experiments were conducted to evaluate the feasibility of biodegrading MTBE by indigenous microorganisms under aerobic, cometabolic, iron reducing, and methanogenic conditions. Results from the field investigation and microbial enumeration indicate that the intrinsic biodegradation of MTBE and BTEX is occurring and causing the decrease in MTBE and BTEX concentrations. Microcosm results show that the indigenous microorganisms were able to biodegrade MTBE under aerobic conditions using MTBE as the sole primary substrate. The detected biodegradation byproduct, tri-butyl alcohol (TBA), can also be biodegraded by the indigenous microorganisms. In addition, microcosms with site groundwater as the medium solution show higher MTBE biodegradation rate. This indicates that the site groundwater might contain some trace minerals or organics, which could enhance the MTBE biodegradation. Results show that the addition of BTEX at low levels could also enhance the MTBE removal. No MTBE removal was detected in iron reducing and methanogenic microcosms. This might be due to the effects of low dissolved oxygen (approximately 0.3 mg/L) within the plume. The low iron reducers and methanogens (<1.8×103 cell/g of soil) observed in the aquifer also indicate that the iron reduction and methanogenesis are not the dominant biodegradation patterns in the contaminant plume. Results from the microcosm study reveal that preliminary laboratory study is required to determine the appropriate substrates and oxidation-reduction conditions to enhance the biodegradation of MTBE. Results suggest that in situ or on-site aerobic bioremediation using indigenous microorganisms would be a feasible technology to clean up this MTBE-contaminated site. 相似文献