土壤石油烃污染的植物毒性及植物-微生物联合降解

通过盆栽实验研究了土壤石油烃污染对玉米和水稻根伸长的影响,并在土壤中接种经过筛选得到的石油烃降解菌,研究石油烃降解菌对石油烃毒性的影响以及对土壤中石油烃的降解。研究结果表明,石油烃浓度低于1 000 mg/kg时对玉米的根系生长有一定的刺激生长作用,随着石油烃浓度的增加,刺激根长生长的作用逐渐降低,研究结果表明,水稻根长受石油烃影响较小。通过对不同处理土壤中石油烃降解的研究结果表明,土壤中种植水稻对石油烃有一定的降解作用,但是不同处理下土壤中的石油烃降解率不同,其中水稻微生物联合处理下土壤中石油烃的降解速率最快,培养期内的降解效率达到53.3%。     

表面活性剂清洗处理重度石油污染土壤

为了优化表面活性剂清洗处理重度石油污染土壤的方法和具体洗脱条件参数,采集山东省东营市胜利油田污染土壤,研究了阴离子-非离子混合表面活性剂对该土壤中石油类污染物的去除效果。应用化学热洗原理,主要考查了表面活性剂配比、投加量、清洗温度及清洗助剂对去除效果的影响。实验得到的清洗处理最佳条件为：使用LAS与TX-100质量比为8∶2的组合表面活性剂,总表面活性剂浓度为3 g/L,助剂硅酸钠浓度为5 g/L,75℃条件下搅拌1 h。清洗后土壤含油量从20%下降到4.6%,去除率达到76.9%。废水回用实验表明,清洗处理的废水对土壤中石油烃类物质仍有一定的去除效果。废水回用比从30%到100%时,对土壤中石油烃的去除率都可达到55%以上。对废水进行二次回用时仍能去除18.8%的污染物。     

基于超声波-微波耦合效应的石油烃类污染土壤的热脱附规律与参数优化

以邻二甲苯为石油烃类污染物代表,以污染土壤质量的减少量以及冷凝液质量的增加量表征土壤污染物的平均脱附效率,研究了微波-超声波耦合热源处理石油烃类污染土壤的脱附规律。结果表明,在超声波功率恒定(800 W)情况下,增大微波功率(从200 W增到400 W),能显著提升装置内反应温度(从128.3℃增到270.1℃),显示了微波较强的热效应;在微波功率恒定(350 W)情况下,增大超声波功率(从600 W增到1 400 W),对装置升温效果影响不明显(从169.4℃增加到187.9℃),表明了超声波较弱的热效应。超声波/微波耦合热源修复壤土的最优工艺参数为土水比20∶1、超声波功率800 W、微波功率350 W、辐照10 min,相应的最高污染物平均脱附率为77.28%,处理效果优于单热源条件。对于不同的土壤粒径及有机质含量,不同类型土壤的平均脱附率排序为砂土(88.36%)壤土(64.29%)黏土(52.61%);综合考虑土壤介电损耗因子、土壤比热容、土壤通透性影响的结果,土水比最优值设为10∶1;综合考虑土壤颗粒单层吸附/多层吸附作用的结果,土壤污染物浓度最优值为8%(砂土)、4%(壤土、黏土)。     

超声波/紫外线-Fenton反应联用去除克拉玛依土壤中石油类污染物

研究了超声波(ultrasonic)和紫外线(ultraviolet)-Fenton反应联用处理干旱区老化石油污染土壤。土壤TPH含量为30 470 mg/kg,pH值为3,H2O2与Fe比例为50∶1时,H2O2浓度为0.37%、0.74%、1.11%和1.85%在超声波处理6 h土壤TPH去除量分别为4 495、11 983、15 470和19 800 mg/kg;TPH去除量随H2O2/Fe2+增大而增大,H2O2/Fe2+为100∶1时,TPH去除量为12 699 mg/kg。溶液pH值接近中性,H2O2浓度为0.74%,H2O2/Fe2+为50∶1,超声波与UV共同作用2 h和4 h,TPH去除量分别达到14 824和21 821 mg/kg;UV单独作用2 h、4 h对土壤TPH去除量为9 253和12 845 mg/kg。超声波-Fenton反应对1,2-二甲苯降解效果最好,其次为C17-C28的直链及支链烷烃,最低为烃类衍生物。     

石油污染含水层介质表面活性剂脱附净化效应

通过批式振荡及溶出模拟实验研究了十二烷基硫酸钠(SDS)、吐温80(TW80)及脂肪醇聚氧乙烯醚硫酸钠(AES)对石油污染含水层介质的脱附净化效果,考察了振荡时间、SDS浓度、脱附净化流程等对污染物净化效率的影响。结果表明:SDS对石油污染的脱附净化效果优于TW80及AES,适宜的振荡时间为3 h,适宜的SDS浓度为4.0 g·L~(-1);脱附净化流程实验证实,按照流程3(首先采用去离子水脱附,然后采用4.0 g·L~(-1)的SDS溶液进行脱附,最后采用去离子水脱附)进行脱附净化后,污染物溶出浓度最低,推荐流程3作为适宜的脱附净化流程。经上述推荐的实验条件处理后,含水层介质溶出模拟实验中TPH浓度降低了99%以上,接近地下水质量标准Ⅳ类限值;苯浓度降低超过了87%,低于地下水质量标准Ⅳ类限值,污染含水层环境及人体健康风险大大降低。基于SDS的脱附净化技术是一种有工程应用前景的石油污染含水层介质修复技术。     

表面活性剂CMC对石油烃污染土壤的增溶

研究了表面活性剂羧甲基纤维素钠(carboxyl methyl cellulose,CMC)对土壤中石油污染物的增溶作用。通过批实验,对比研究了CMC和十二烷基苯磺酸钠SDBS 2种表面活性剂的增溶效果,探究了CMC浓度、pH、盐度及回用次数对土壤中石油烃增溶效果的影响。研究结果表明,当CMC浓度为0.5%,增溶时间为24 h时,对TPHs浓度为17 695 mg·kg~(-1)的污染土样,TPHs洗脱率高达60%以上。碱性环境有利于石油烃的洗脱,酸性体系会抑制石油烃的洗脱;增溶作用随盐度的增大而显著增大。在利用CMC对污染土壤进行增溶洗脱时,对于TPHs高浓度污染土壤,可以选择将其洗脱液回用1次或者2次;对于TPHs较低浓度污染土壤,可以选择将其洗脱液回用于较高浓度的污染土壤。     

矿化垃圾修复石油污染土壤的影响因素及污染物的去除机制

利用矿化垃圾对石油污染土壤进行修复研究,以期在低成本、易操作、修复效果好的前提下达到以废治废的目的。分别研究了矿化垃圾与石油污染土壤的混合比例、土壤含盐量、含油量和含水率对矿化垃圾修复石油污染土壤的影响,并通过3D-EEM(三维荧光)和GC-MS(气相-质谱)技术分析了体系石油污染物的去除特性。结果表明:矿化垃圾对石油污染土壤具有较好的修复效果,在矿化垃圾与石油污染土壤的混合比例为6:4、土壤不添加盐分、含油量为4%、含水率为30%的条件下,运行94 d后土壤中石油去除率最高可达58.61%;同时,基于3D-EEM分析发现土壤中石油类物质的荧光峰位置在处理前后均出现在Ex/Em=300 nm/330 nm处,其去除率为44.89%,表明矿化垃圾床对三环及其同系物和单环及其同系物的芳烃去除效果较好;另外,基于GC-MS技术分析得出,经矿化垃圾修复后,土壤中石油总去除率为66.57%,除正十八烷去除率(19.84%)较低外,其他烷烃的去除率均高于56.8%。     

不同处理条件对石油污染土壤植物修复的影响

针对石油烃植物修复过程中的主要影响因素,研究了不同植物种类、不同土壤调理剂和菌剂使用等不同条件对土壤中石油烃植物修复效果的影响.结果表明,不同种类的植物修复可使总石油烃的年降解率达到37.8％ ～ 73.98％,其中大豆和碱蓬具有较好的修复效果;3种不同土壤调理剂对石油烃污染土壤修复的效果为商业添加剂＞牛粪＞蛭石;先微生物修复后种植植物的处理要优于单独的微生物修复及微生物、植物修复同步进行的处理.     

活化过硫酸钠原位修复浅层石油烃类污染土壤的模拟研究

以过硫酸钠为氧化剂,硫酸亚铁为活化剂,通过箱体实验,结合农业滴灌技术,原位化学氧化修复浅层石油烃(TPH)污染土壤,考察修复过程中土壤TPH、含水率、电导率、pH的变化情况。结果表明,硫酸亚铁活化过硫酸钠对土壤中TPH具有较好的去除作用,通过40d的原位修复处理,表层土和中层土中的TPH去除率分别达到44.6%、44.1%;修复过程中,表层土含水率、电导率呈先上升后下降的趋势,中层土含水率、电导率则先上升后波动变化,表层土、中层土pH均呈先下降后上升的趋势;土壤TPH与含水率、电导率、pH间均存在相互制约的关系。     

表面活性剂强化电动修复石油污染土壤的机制研究

采用表面活性剂强化电动修复石油污染土壤,通过分析石油烃及其组分的变化特征,探讨了表面活性剂强化作用下污染物的去除机制.结果表明,单一电动修复处理(EK)下土壤总石油烃(TPH)的平均去除率为12.50％,用十二烷基苯磺酸钠(SDBS)和聚氧乙烯月桂醚(Brij35)及其混合溶液(SDBS/Brij35)作为电解液强化电...     

Combination of biochar amendment and phytoremediation for hydrocarbon removal in petroleum-contaminated soil

Remediation of soils contaminated with petroleum is a challenging task. Four different bioremediation strategies, including natural attenuation, biochar amendment, phytoremediation with ryegrass, and a combination of biochar and ryegrass, were investigated with greenhouse pot experiments over a 90-day period. The results showed that planting ryegrass in soil can significantly improve the removal rate of total petroleum hydrocarbons (TPHs) and the number of microorganisms. Within TPHs, the removal rate of total n-alkanes (45.83 %) was higher than that of polycyclic aromatic hydrocarbons (30.34 %). The amendment of biochar did not result in significant improvement of TPH removal. In contrast, it showed a clear negative impact on the growth of ryegrass and the removal of TPHs by ryegrass. The removal rate of TPHs was significantly lower after the amendment of biochar. The results indicated that planting ryegrass is an effective remediation strategy, while the amendment of biochar may not be suitable for the phytoremediation of soil contaminated with petroleum hydrocarbons.     

典型禾本科植物对石油污染土壤的修复作用

石油类污染物对土壤生态系统的结构与功能造成了较为严重的破坏,影响植物的生长,甚至直接影响到人类健康。选择典型禾本科植物-高粱和玉米,通过盆栽实验,种植于模拟石油污染的土壤中,植物成熟收割后,通过测定土壤中总石油烃的含量,植物体中多环芳烃和直链烷烃的含量,研究高粱和玉米对石油污染土壤的修复作用。结果显示:在种植高粱、玉米后,土壤中总石油烃含量明显降低,并且在收获的高粱、玉米植物体中直链烷烃和多环芳烃含量明显高于空白对照组(未检出)。说明高粱、玉米对石油烃具有一定的去除作用,且高粱对土壤中石油烃的去除作用高于玉米;高粱、玉米对土壤中的多环芳烃和直链烷烃具有一定的积累与富集作用。     

Phytoremediation of an aged petroleum contaminated soil using endophyte infected and non-infected grasses

Phytoremediation is a promising technique for cleaning petroleum contaminated soils. In this study, the effects of two grass species (Festuca arundinacea Schreb. and Festuca pratensis Huds.), infected (E(+)) and non-infected (E(-)) by endophytic fungi (Neotyphodium coenophialum and Neotyphodium uncinatum, respectively) on the degradation of petroleum hydrocarbons in an aged petroleum contaminated soil was investigated. Plants were grown in the soil for 7 months and unplanted soil considered as control. At the end of the experiment, total and oil-degrading bacteria, dehydrogenase activity, water-soluble phenols, total petroleum hydrocarbons (TPH) and polycyclic aromatic hydrocarbons (PAHs) contents were measured in the soil. The results demonstrated that E(+) plants contained more root and shoot biomass than E(-) plants and created higher levels of water-soluble phenols and dehydrogenase activity in the soil, while there was no significant difference in bacterial counts of planted soils. Planting stimulated total and oil-degrading bacterial numbers, dehydrogenase activity and the soil content of water-soluble phenols. Regardless of endophyte infection, PAH and TPH removal in the rhizosphere of plants were 80-84 and 64-72% respectively, whereas the removals in controls were 56 and 31%, respectively. It was revealed that TPHs in retention time range of n-alkanes with C(10)-C(25) chain lengths and TPH were more degraded in the rhizosphere of E(+) plants compared to E(-) ones. Thus, grasses infected with endophytic fungi could be more efficient for removal of TPH from oil-contaminated soils.     

石油污染土壤的植物与微生物修复技术

石油污染土壤的生物修复技术具有成本低、简便高效、对环境影响小等优点,正逐步成为石油污染治理研究的热点领域,具有广阔的发展前景.介绍了我国的石油污染概况及生物修复技术在石油污染治理中的应用,重点对石油污染土壤的微生物修复、植物修复、植物一微生物联合修复技术的研究进展及各自的优点、局限性进行了综述,并提出了石油污染土壤生物修复技术研究的重点领域.     

Root establishment of perennial ryegrass (L. perenne) in diesel contaminated subsurface soil layers

The efficiency of rhizosphere biodegradation of petroleum hydrocarbons heterogeneously distributed in soils is dependent on the ability of plant roots to prospect into contaminated zones. Rhizobox experiments were conducted to study the influence of diesel contaminated layers on the spatial distribution and the development of the roots of perennial ryegrass. Root distribution and root and shoot development were monitored over time. The final root and above ground biomass and the final TPH concentration were determined. The spatial distribution of the contaminant as well as the irrigation method used affected root distribution, plant development and TPH degradation and therefore ryegrass remediation potential. The results show that roots colonise fully uncontaminated soil and grow preferentially between zones of contamination. Conversely, when no immediate uncontaminated soil is available, roots grow through contaminated zones in order to prospect for uncontaminated soil.     

Fenton氧化技术处理稠油污染土壤

利用Fenton氧化技术对稠油污染土壤进行氧化处理,分析对后续微生物修复的促进作用。向1 000 g石油类含量为8%的稠油污染土壤中加入10.0 mL 18 mmol/L Fe2+溶液与10.0 mL 30%H2O2,反应时间为2 h。氧化处理后土壤中石油烃的总去除率可达到31.38%,胶质去除率为45.22%,沥青质去除率为51.26%,胶质的分子量由1 841下降到1 472,沥青质的分子量由5 831下降到5 073。Fenton氧化可使土壤酶活、各类微生物的数量及呼吸强度有不同程度的下降,但在氧化后30 d内,土壤各类微生物数量都超过了原有水平,其中细菌数量最高达到9.84×105CFU/g,是氧化前的数量的1.57倍。以上实验结果表明,Fenton氧化可以有效去除土壤中胶质和沥青质,并且使土壤中微生物的生长速率加快。因此,Fenton氧化能够促进后续的微生物修复。     

A field trial for an ex-situ bioremediation of a drilling mud-polluted site

The remediation of drilling mud-polluted sites in the Southeast of Mexico is a top priority for Mexican oil industry. The objective of this work was to find a technology to remediate these sites. A field trial was performed by composting in biopiles, where four 1ton soil-biopiles were established, one treatment in triplicate and one unamended biopile. Amended biopiles were added with nutrients to get a C/N/P ratio of 100/3/0.5 plus a bulking agent (straw) at a soil/straw ratio of 97/3. Moisture content was maintained around 30-35%. Results showed that, after 180 d, total petroleum hydrocarbon (TPH) concentrations decreased from 99300+/-23000mgTPHkg(-1) soil to 5500+/-770mgTPHkg(-1) for amended biopiles and to 22900+/-7800mgTPHkg(-1) for unamended biopile. An undisturbed soil control showed no change in TPH concentrations. Gas chromatographic analysis showed residual alkyl dibenzothiophene type compounds. Highest bacterial counts were observed during the first 30 d which correlated with highest TPH removal, whereas fungal count increased at the end of the experimentation period. Results suggested an important role of the straw, nutrient addition and water content in stimulating aerobic microbial activity and thus hydrocarbon removal. This finding opens an opportunity to remediate old polluted sites with recalcitrant and high TPH concentration.     

Bioremediation of diesel-contaminated soil with composting

The major objective of this research was to find the appropriate mix ratio of organic amendments for enhancing diesel oil degradation during contaminated soil composting. Sewage sludge or compost was added as an amendment for supplementing organic matter for composting of contaminated soil. The ratios of contaminated soil to organic amendments were 1:0.1, 1:0.3, 1:0.5, and 1:1 as wet weight basis. Target contaminant of this research was diesel oil, which was spiked at 10,000 mg/kg sample on a dry weight basis. The degradation of diesel oil was significantly enhanced by the addition of these organic amendments relative to straight soil. Degradation rates of total petroleum hydrocarbons (TPH) and n-alkanes were the greatest at the ratio of 1:0.5 of contaminated soil to organic amendments on wet weight basis. Preferential degradation of n-alkanes over TPH was observed regardless of the kind and the amount of organic amendments. The first order degradation constant of n-alkanes was about twice TPH degradation constant. Normal alkanes could be divided in two groups (C10-C15 versus C16-C20) based on the first order kinetic constant. Volatilization loss of TPH was only about 2% of initial TPH. Normal alkanes lost by volatilization were mainly by the compounds of C10 to C16. High correlations (r=0.80-0.86) were found among TPH degradation rate, amount of CO2 evolved, and dehydrogenase activity.