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1.
采用原位修复法处理石油烃污染土壤,考察了土壤中石油烃的自然降解情况,研究了土壤改良剂和生物营养剂对石油烃降解的促进作用。实验结果表明:将总石油烃含量约为5 g/kg的实验土样降解30 d,自然降解时总石油烃降解率为7.8%;当单独加入1.0%(w)的土壤改良剂时,总石油烃降解率达36.0%;当单独加入1.0 g/kg的生物营养剂时,总石油烃降解率为51.6%;最佳促进剂配方为土壤改良剂加入量1.0%(w),生物营养剂加入量1.0 g/kg,此条件下总石油烃降解率为80.1%。 相似文献
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从陕北原油污染土壤中筛选出7株高效石油烃降解菌,其中黄杆菌属CC-2、不动细菌属SC-5、假单胞菌属SC-6表现出较强的石油烃降解能力。通过单因素试验和正交试验考察总石油烃(TPH)降解效果的影响因素,得出各因素对TPH降解率影响程度的大小次序为:溶液p H降解温度降解菌接种量摇床转速,且在降解菌接种量为7%(φ)、溶液p H为7、降解温度为30℃、摇床转速为150 r/min的最适处理条件下,菌株SC-6的TPH降解率可达61.23%。原油污染土壤生物修复实验结果表明:高效石油烃降解菌的投加有利于土壤TPH降解率和酶活性的提高;"菌株SC-6+营养剂"组修复处理42 d后的TPH降解率可达57.59%。 相似文献
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微生物降解重油的初步研究 总被引:3,自引:1,他引:2
丛石油污染的土壤中筛选出一株假单胞菌,考察了其对重油的降解效果。降解18d,重油的降解率达到42.8%,饱和烃、芳香烃、胶质、沥青质的降解率分别为42.95%,43.85%,44.5%,5.55%;质量浓度2.5g/L的表面活性剂Tween-80可使重油的18d降解率达到51.0%;弱碱性条件有利于重油的生物降解;生物泥浆法处理重油污染的土壤,1kg土壤中重油质量100g,降解45d,重油的降解率达到38.85%。 相似文献
4.
以盆栽实验为基础,研究了植物(黑麦草,Lolium perenne L)-微生物(不动杆菌,Acinetobacter sp.)组合体系对石油污染土壤的修复效果。实验结果表明:在总石油烃含量为4 420.18 mg/kg、脱氢酶活性为230.52 μg/(g·d)、苯酚毒性当量浓度(TEQphenol)为1 633.21 mg/L的初始条件下,强化组总石油烃降解率最高为53.08%,是对照组的1.60倍;土壤的脱氢酶活性达到637.73 μg/(g·d),是对照组的10.64倍;石油污染土壤的生物毒性大幅降低, TEQphenol最终降低至171.08 mg/L。说明该组合体系对石油污染土壤具有很好的修复作用,且微生物对土壤中有毒物质的降解起主要作用。 相似文献
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选取4种从石油污染土壤中分离出的石油降解菌(包括根瘤菌(A)、节细菌(B)、嗜盐菌(C)和芽孢杆菌(D)),对模拟石油污染土壤进行了微生物修复实验。考察了4种菌单独使用时的石油降解率,确定了混合菌的最佳配比和菌群的最优培养条件,并对比了微生物修复前后土壤的各项性质。实验结果表明:4种菌均可提高微生物修复石油污染土壤的修复效果,使用D菌时石油降解率最高;当混合菌的w(A)∶w(B)∶w(C)∶w(D)=12∶2∶21∶65时,在培养条件为混合菌接种量122.0 mL/kg、土壤含水率14%(w)、鸡粪加入量90 g/kg、麦糠加入量150 g/kg和表面活性剂加入量22 mL/kg的情况下,土壤的修复效果最好,40 d后石油降解率达66.95%;经混合菌修复的石油污染土壤,其肥力明显升高,脱氢酶、过氧化酶和脲酶的活性均升高,微生物数量也有明显增加。 相似文献
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选取4种从石油污染土壤中分离出的石油降解菌(包括根瘤菌(A)、节细菌(B)、嗜盐菌(C)和芽孢杆菌(D)),对模拟石油污染土壤进行了微生物修复实验。考察了4种菌单独使用时的石油降解率,确定了混合菌的最佳配比和菌群的最优培养条件,并对比了微生物修复前后土壤的各项性质。实验结果表明:4种菌均可提高微生物修复石油污染土壤的修复效果,使用D菌时石油降解率最高;当混合菌的w(A)∶w(B)∶w(C)∶w(D)=12∶2∶21∶65时,在培养条件为混合菌接种量122.0 mL/kg、土壤含水率14%(w)、鸡粪加入量90 g/kg、麦糠加入量150 g/kg和表面活性剂加入量22 mL/kg的情况下,土壤的修复效果最好,40 d后石油降解率达66.95%;经混合菌修复的石油污染土壤,其肥力明显升高,脱氢酶、过氧化酶和脲酶的活性均升高,微生物数量也有明显增加。 相似文献
7.
从柴油污染土壤中筛选分离出一株高效降解柴油的菌株CY-1,考察了自然衰减修复、生物刺激修复、生物强化修复以及生物刺激-生物强化联合修复等4种修复方法对土壤中柴油的降解能力及降解过程中几种土壤微生物酶活性的变化。实验结果表明:该菌为假单胞菌属;采用生物刺激-生物强化联合修复初始柴油质量分数为2.70%的柴油污染土壤,经过31 d的降解,柴油质量分数降至1.09%,柴油去除率达59.6%;经生物刺激-生物强化联合修复,土壤脱氢酶活性和荧光素二乙酸酯水解酶活性最高;通过生物刺激处理可使土壤脲酶活性和磷酸酶活性达到最高。 相似文献
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共基质和无机盐对原油降解菌株降解原油效果的影响 总被引:1,自引:1,他引:0
从大港油田石油污染土壤中分离筛选出1株原油降解菌X3,对原油的降解率达72.6%,经鉴定X3菌株属于假单胞菌属(Psedomonas)。利用生物摇床对X3菌株降解原油的实验发现,共代谢基质α-乳糖对X3菌株降解原油有促进作用,可使原油降解率提高到80.3%;而葡萄糖和蔗糖对X3菌株降解原油有抑制作用。Fe2+对X3菌株的降解原油也有促进作用,在α-乳糖和Fe2+的共同作用下,X3菌株对原油的降解率可达82.3%;K+和Mg2+对X3菌株降解原油则有抑制作用。在FeSO4质量浓度为0.2~0.3mg/L时,X3菌株对原油的降解率最高,FeSO4质量浓度继续增加,X3菌株对原油的降解率下降。 相似文献
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Turlough F. Guerin 《补救:环境净化治理成本、技术与工艺杂志》2001,11(3):129-143
Land treatment facilities can provide effective treatment of secondary oily wastewater from maintenance operations, particularly in arid climates. Soil and underlying groundwater from a land treatment facility, which has been operating for eight years, were analyzed to determine the effectiveness of using bioremediation for the treatment of dissolved and free‐phase oil in maintenance wastewater. The study was conducted at a mining site in Western Australia. The facility was capable of treating 140 kiloliters (kL) of oily wastewater per day. The average petroleum hydrocarbon content of the wastewater was 2 percent weight per volume (w/v) based on data available for the first five years. The soil data indicate that the land treatment process has been operating efficiently even at high wastewater loadings with maximum degradation rates of 10–242 mg/kg per day. Based on the soil data, there is no evidence of accumulation of any metal or polycyclic aromatic hydrocarbon (PAH) compounds. The land treatment facility has led to only low levels of TPH (total petroleum hydrocarbons) contamination (<4 ppm) in the underlying groundwater. However, nitrate concentrations in the groundwater were shown to increase over the first five years of the facility's operation. This article reports and discusses the operational data from the land treatment process, illustrating its effectiveness in treating oily wastewater. © 2001 John Wiley & Sons, Inc. 相似文献
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为解决石油污染土壤中以石油为唯一碳源的土著微生物生长缓慢的问题,研究了分别添加玉米淀粉、玉米粉、可溶性淀粉和葡萄糖4种碳源对土样细菌总量和石油烃降解率的影响。研究结果表明:玉米淀粉作为碳源时土样TN和TP的下降幅度均最大;添加玉米淀粉和玉米粉比添加可溶性淀粉和葡萄糖更有利于细菌的生长繁殖;细菌对直链烷烃化合物均具有较好的降解效果,但对较为复杂的芳香烃化合物降解效果较差。降解反应第40天时,分别添加玉米淀粉、玉米粉、可溶性淀粉和葡萄糖的石油烃降解率分别为67.25%、48.60%、46.30%和28.57%。 相似文献
13.
Traditional bioremediation approaches have been used to treat petroleum source contamination in readily accessible soils and sludges. Contamination under existing structures is a greater challenge. Options to deal with this problem have usually been in the extreme (i.e., to dismantle the facility and excavate to an acceptable regulated residual, or to pump and treat for an inordinately long period of time). The excavated material must be further remediated and cleanfill must be added to close the excavation. If site assessments were too conservative or incomplete, new contamination adulterating fill soils may result in additional excavation at some later date. Innovative, cost-efficient technologies must be developed to remove preexisting wastes under structures and to reduce future remediation episodes. An innovative soil bioremediation treatment method was developed and evaluated in petroleum hydrocarbon contaminated (PHC) soils at compressor stations of a natural gas pipeline running through Louisiana. The in-situ protocol was developed for remediating significant acreage subjected to contamination by petroleum-based lubricants and other PHC products resulting from a chronic leakage of lubricating oil used to maintain the pipeline itself. Initial total petroleum hydrocarbon (TPH) measurements revealed values of up to 12,000 mg/kg soil dry weight. The aim of the remediation project was to reduce TPH concentration in the contaminated soils to a level of <200 mg/kg soil dry weight, a level negotiated to be acceptable to state and federal regulators. After monitoring the system for 122 days, all sites showed greater than 99-percent reduction in TPH concentration. 相似文献
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As a result of former industrial activities, many properties across the United States contain various chemicals in their soils at concentrations above background levels. Polynuclear aromatic hydrocarbons (PAHs) are often encountered at sites of gas manufacture, wood treating, tar refining, coke making, and petroleum reflning. When the presence of PAHs in site soil is deemed to create a situation of unacceptable risk to public health or the environment, treatment or disposal is required to reduce concentrations to acceptable levels. The ideal remedial process for PAHs in soils would destroy them to an environmentally sound level at relatively low cost without producing adverse by-products. In many cases bioremediation can accomplish these goals. The degree to which bioremediation can destroy PAHs in a particular soil, however, is highly dependent on the characteristics of that soil, including the nature of the hydrocarbon that is the source of the PAHs. It is the objective of this article to describe efforts leading to this conclusion and to summarize how soil characteristics influence bioremediation of PAHs. 相似文献
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《Waste management & research》1994,12(2):173-194
The evaluation and selection of technologies for the effective remediation of hydrocarbon-contaminated sites requires careful consideration of the waste/site/soil characteristics that determine their ultimate success. The presence of weathered hydrocarbon wastes and sub-optimal environmental conditions places technical restraints on the bioremediation of polynuclear aromatic hydrocarbon-contaminated soils. A brief overview of applicable bioremediation technologies is followed by an indepth critical evaluation of limiting factors that can influence the efficacy of biotreatment options, including waste composition, temperature, substrate, bioavailability, accompanying toxicants and soil structure. 相似文献