共查询到18条相似文献,搜索用时 125 毫秒
1.
《吉林大学学报(地球科学版)》2015,(Z1)
<正>苯酚等酚类物质作为一种重要的化工原料,在造纸、木材加工、塑料、纺织、染料和农药的生产制造中得到了大量应用,同时酚类污染物也是最典型的一类环境内分泌干扰物,对几乎所有生物体有毒杀作用,在大气、土壤和水体环境中广泛存在[1]。与物理化学方法相比,固定化微生物技术因具有操作简单、成本低廉、反应速度快、耐环境冲击、降解效率高的特点[2],在处理苯酚类污染的废水中具有得天独厚的优势。本研究将华南地区石油污染土壤中筛选出的能降解多种多环芳烃和酚类化合物的高效降解菌——鞘 相似文献
2.
《地球科学进展》2015,(10)
回顾了近10年来完整极性脂质化合物(IPLs)在海洋微生物研究中的应用及存在的问题,并展望了IPLs应用的发展前景。作为新的热点之一,对海洋水体悬浮颗粒物中IPLs的研究,不仅推进了人们对水柱中IPLs分布和转化的了解,同时也深化了对古环境指标TEX86适用性的认识,有助于更好地开展古环境重建研究。色谱和质谱技术的发展,新型化合物的发现以及IPLs单体碳同位素分析的应用,使得IPLs在示踪海洋环境中真核生物与微生物共生作用、微生物介导的好氧和厌氧氨氧化以及甲烷厌氧氧化作用、微生物的代谢状态等方面也取得了重要研究进展。需要注意的是,由于不同的IPLs降解速率并不一致,其中部分古菌糖脂的降解周期可能远大于微生物群落的更新周期,因此可能并不适于表征活体生物量;同时,环境中氧气含量及有机质浓度也会对IPLs的降解速率造成影响;另外,在微生物不同的生长阶段,或者微生物由于生长环境条件变化产生生理响应时,IPLs组成也可能会发生变化。因此,应用IPLs指示微生物活动和反演古环境时应注意指标的适用性。 相似文献
3.
产氢菌的发现是近代微生物学研究的一大重要进展。地质体中的氢代谢(氢的生成和利用)是微生物降解有机质形成烃类的重要环节。在石油生成过程中,氢是重要的中间产物及主产物。大分子化合物分解为小分子化合物、脱去含氧基团、烯烃成为饱和烃均需要补充氢。没有氢代谢便没有石油的大量生成。产氢菌含有氢化酶,具有生成H2的能力。一部分微生物在降解有机质的过程中形成H2,另一部分微生物利用H2进行生命活动,产氢耗氢一直处于一种稳定的动态平衡,产氢微生物只有在耗氢微生物存在下才能生长。耗氢微生物的耗氢作用又促进了产氢反应的连续进行,这种微生物的互营联合,发生在石油形成过程中的各个阶段。氢转移是厌氧降解有机质区别于有氧降解有机质的最重要特征。微生物生长繁殖受温度、营养及沉积环境的影响,从浅层至深层,微生物种群不断更替,原有的种群因环境改变而死亡,新的种群又会大量繁殖,死亡的微生物输入至沉积层便成为烃类。酶是一种具有催化活性的蛋白质,微生物的一切生命活动都离不开酶。一种酶只能催化一种反应或一类反应的完成,各阶段都有独特的酶系统,酶在完成专属代谢途径后,可转化成石油组分,如叶绿素转化成甲烷菌F430辅酶,再转化成卟啉。地层温度促进了有机质热裂解,使有机质中的C-C键断裂发生得更加频繁;厌氧微生物的降解作用也使有机质发生降解。二者方向相同,互为融合,使有机质的裂解加速。微生物对有机质改造形成烃类,其中脱去含氧官能团、产氢用氢形成饱和烃等作用,对讨论石油和天然气的形成具有重要意义。 相似文献
4.
当地下水邂逅DNA:石油类有机污染及其生物降解 总被引:1,自引:0,他引:1
地下水科学与工程研究发展到今日,已经成为一门涉及多个领域的综合性学科。地下水污染的控制和修复研究更需要跨学科的技术和知识支持,而生物修复作为一种高效低耗修复的技术成为环境领域的研究热点。微生物因其自身特性及其对污染的降解主导特征对确定有机物污染场地的永续修复具有重要意义。简要地综述了地下水有机污染及其原位修复、有机污染物和地下环境微生物的交互作用,进一步聚焦生物降解机制、生物修复和细菌研究。在此基础上以某石油污染场地地下水为例,进行了地下水中分离微生物菌株及其降解特征的实验研究。结果表明:放线菌降解效果最好,细菌和真菌次之;两两组合降解效果好于单菌,表明存在协同作用;不同菌株混合降解率较低,表明具有拮抗作用。通过动力学实验得出对TPH的降解符合一级反应动力学方程及其降解速度和降解半衰期。就微生物对有机组分降解而言,烷烃和总石油烃降解规律相似;难降解组分降解率低,后期因烷烃转化使其浓度升高;苯浓度变化不大。微生物活性实验表明:活菌总数和脱氢酶活性与降解率呈正相关变化。运用生理生化及分子生物学方法鉴定得出了具体的菌种。 相似文献
5.
利用高效本源降解菌在不同时间范围内对辽河油样进行了微生物降解模拟实验,以研究不同降解程度原油分子结构的变化规律。微生物作用前后原油样品做族组分分离及进一步的中性氮化合物和酸性化合物分离,然后对其不同组分进行色谱质谱分析和红外光谱分析。结果表明,辽河油样中的非烃化合物经微生物作用以后,正构一元酸含量随降解时间的增加而增加,且变化幅度逐渐增大;五环三萜类羧酸中C28组分和莫烷酸系列随着降解时间的增加含量上升;轻度的微生物降解作用对咔唑、甲基咔唑、二甲基咔唑等化合物没有明显影响,中等强度降解具有一定的影响;从胶质、沥青质红外光谱图看出,微生物能够降解该原油胶质、沥青质。侧链长度随降解程度增加而变短;芳香环结构抗微生物降解能力强,缩合程度变化不大;而取代基上的烷烃易被微生物氧化,氧化程度随降解程度增加而增加,产生酸类、醚类物质。探讨原油微生物降解中非烃化合物结构及其地球化学特征对石油勘探开发都有重要指导作用。 相似文献
6.
贵州红枫湖沉积物有机质的酶及微生物降解 总被引:8,自引:1,他引:8
文章通过DNA、α-葡萄糖苷酶和硫酸盐还原菌等的变化,研究了贵州红枫湖沉积物中有机质的酶及微生物降解.有机质在微生物及其分泌的胞外酶的作用下被降解,在沉积物深度11cm以下被降解到相对较低的含量.DNA的分布表明表层9cm的沉积物深度内微生物的活动较为强烈,是微生物降解有机质的主要位置.α-葡萄糖苷酶在悬浮层含量最高,达0.75μmol/min*g干沉积物,提示有机质中的淀粉和糖原等物质在悬浮层降解较为激烈,被大量分解;随着沉积物深度的增加α-葡萄糖苷酶活性减弱,在有机质降解明显开始变缓的11cm沉积物中,α-葡萄糖苷酶活性已降低到0.17μmol/ming干沉积物.分子生物学的研究表明红枫湖沉积物表层7cm是硫酸盐还原菌的主要分布位置,结合有机质和SO2-4含量的研究结果,提示红枫湖沉积物中SO2-4不可能成为有机质氧化的主要电子受体,硫酸盐还原的限制因素也不是有机质供应. 相似文献
7.
利用实验室含水层物质微环境实验,对地下水中常见有机污染物苯和甲苯在厌氧反硝化条件下的微生物降解进行了研究。通过10种方案实验结果的分析对比,所得重要结论如下:在加强了的反硝化条件下,微生物利用NO-3作为电子受体降解苯和甲苯;降解苯和甲苯的反硝化细菌来自于含水层物质;微生物所需的宏量营养由苯、甲苯和硝酸盐提供,痕量元素来自于含水层物质;环境的酸碱条件对微生物降解具有重要影响,pH值过高或过低均抑制微生物降解作用的产生。 相似文献
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9.
微生物降解蒙脱石层间吸附有机质的实验研究 总被引:1,自引:0,他引:1
近年来,国内外学者意识到,有机质在蒙脱石结构层间的吸附是有机质保存的重要机理之一,然而,目前关于微生物能否降解蒙脱石层间吸附有机质以及降解的程度等尚没有任何实验数据的支撑。本文试图通过人工合成含有层间吸附有机质的蒙脱石,利用海洋和湖泊沉积物中常见的降解有机质的微生物对其进行降解实验,据此探讨有机质的蒙脱石层间吸附在沉积物埋藏过程中对有机质保存的贡献。有机质选择半胱氨酸和甲苯,前者是生物生长所需的一种重要氨基酸,后者大量存在于土壤和沉积物中,多种细菌可以在有碳氢化合物的环境下将其降解。实验菌种选择恶臭假单胞杆菌(Pseudomonas putida)和腐败希瓦氏菌(Shewanella putrefaciens CN32)2种细菌,它们均为海洋和湖泊沉积物中的主导微生物,前者有较强的有机质降解能力,后者为铁的还原菌,厌氧代谢过程中能将蒙脱石结构中的Fe(III)还原为Fe(II)。通过上述不同菌种对蒙脱石层间吸附不同性质有机质的降解实验,结果显示,微生物对蒙脱石层间吸附的有机质的降解方式主要有分泌有机酸直接降解和破坏层间结构释放有机物从而进行降解。代表菌种假单胞菌和希瓦氏菌对半胱氨酸绿脱石及甲苯绿脱石的作用表明,微生物通过分泌有机酸的形式对蒙脱石层间吸附的有机质降解作用很有限,该结构在恒定的有氧和无氧条件下对保存有机质有利;希瓦氏菌在严格无氧条件下通过还原Fe(III)进行代谢,实验表明,无氧条件下,希瓦氏菌可以一定程度破坏矿物结构,释放并消耗有机物,因此,铁还原微生物对蒙脱石层间吸附有机质的保存有一定的影响,但由于微生物对矿物晶体结构的破坏能力有限,故其对层间吸附有机质降解的能力也有限;不同有机物对生物降解过程也有影响,这些影响取决于有机质的特性及有机质与细菌之间的相互作用。绿脱石层间吸附的半胱氨酸对生物生长有利,从而可能促进生物还原Fe(III)作用。相反,甲苯却很明显的抑制了Fe(III)的还原。由此可见,有机质的蒙脱石层间吸附是有机质保存的重要方式之一。 相似文献
10.
王万春 《矿物岩石地球化学通报》2007,26(3):269-275
微生物降解使有机化合物的稳定碳、氢同位素发生不同程度分馏的研究在有机污染物来源和微生物环境修复等领域取得了长足进展,并对原油和天然气微生物降解研究有借鉴意义。微生物作用下的同位素分馏为动力同位素分馏,导致重同位素在残余物中富集。影响微生物降解有机物同位素分馏的主要因素有微生物的降解代谢途径、辅酶作用、降解类型与程度、同位素质量差异和有机物碳数等。不同的微生物代谢途径代表不同的生物化学反应,造成了同位素分馏的显著差异;辅酶对反应的催化作用使微生物作用造成的同位素分馏更加复杂。低碳数正构烷烃遭受微生物降解程度越高,碳、氢同位素的分馏也越大,同位素变重与降解程度之间有明显的相关性。但对于复杂化合物,由于降解的多级反应,同位素分馏与降解程度间的相关性并不明显。在同样降解程度下,氢同位素分馏大于碳同位素分馏,低碳数正构烷烃的同位素分馏大于高碳数正构烷烃的同位素分馏。 相似文献
11.
采用离散元法(DEM)研究胶结岩土材料在不同加载条件下的结构破损规律。首先,基于微观力学理论,考虑胶结岩土材料颗粒间胶结特性,给出表征结构性损伤的破损参数式。该式具有微观物理意义,但不能直接用于建立宏观本构模型。其次,采用二维离散元源程序NS2D模拟等向压缩、等应力比压缩以及双轴压缩试验,分析破损参数在不同加载条件下随宏观力学变量(体积应变和剪应变)的演变规律。最后,根据模拟结果提出破损参数数学表达式,其为大主应变的函数。研究结果表明:胶结强度、应力比以及围压均在一定程度上影响了数值试样的结构破损规律。在等向压缩和等应力比压缩试验中,容易用函数式描述数值试样破损参数随体积应变或偏应变的演变规律;而在双轴压缩条件下,由于数值试样有剪胀特性,破损参数随体积应变的演变规律则不易描述。建议的破损参数数学表达式能够较好地描述数值试样在不同加载条件下结构破损规律。 相似文献
12.
A. Khanafari Ph.D. A. Akhavan Sepahei Ph.D. 《International Journal of Environmental Science and Technology》2007,4(4):427-432
The potential of three Azotobacter chroococcum strains for whey degradation and alginate production were investigated. After dilution, samples were spread plated on isolation agar and Manitol agar and incubated at 30 °C for 24 h. Microorganisms were screened for their ability to whey degradation and alginate production based on colony morphology, negative and capsule staining, ability to decrease the apparent turbidity of the fermentation broths in batch and semi continuous culture by spectrophotometer assay at 400 nanometer and tensiometer assay. Of the three strains tested for whey degradation, only Azotobacter chroococcum 1723 produced significant apparent growth on whey broth and could decrease about 70 % of turbidity in fermentation broth during 6 days in batch culture. Colonies of this strain was characteristically yellow, large, moucoid and slimy on whey agar than Manitol agar after 24 h at 30 °C. Transmission electron microscopy assay and Carbazole reagent were used to recognize the alginate biopolymer. After optimizing environmental factors such as pH, salt concentration and temperature, this strain was able to produce exopolysaccharide greater than 5 mg/mL. Optimum results were obtained when using whey broth as a fermentation medium without extra salt, temperature at 35 °C and pH 7. Increasing inorganic and organic nitrogen sources (yeast extract and NH4NO3) reduced whey degradation at least 30%. Transmission electron microscopy assay showed a net-structured polysaccharide capsule around the cells. Semi-continuous culture results demonstrated that, alginate production as well as whey degradation was decreased (1 mg/mL and 30 %). 相似文献
13.
Most existing hydromechanical models for unsaturated soils are not able to fully capture the nonlinearity of stress–strain curves at small strains (less than 1%). They cannot therefore, for example, accurately predict ground movements and the performance of many earth structures under working conditions. To tackle this problem, a state‐dependent bounding surface plasticity model has been newly developed. Particularly, the degradation of shear modulus with strain at small strains ranging from 0.001% to 1% is focused. The proposed model is formulated in terms of mean average skeleton stress, deviator stress, suction, specific volume and degree of saturation. Void ratio‐dependent hydraulic hysteresis is coupled with the stress–strain behaviour. Different from other elastoplastic models for unsaturated soils, plastic strains are allowed inside bounding surfaces. In this paper, details of model formulations and calibration procedures of model parameters are presented. To evaluate the capability of the new model, it is applied to simulate a series of triaxial compression tests on compacted unsaturated silt at various suctions. Effects of suction, drying and wetting as well as net stress on unsaturated soil behaviour are well captured. The model shows good predictions of the degradation of shear modulus with strain over a wide range of strains from 0.001% to 1%. Copyright © 2015 John Wiley & Sons, Ltd. 相似文献
14.
J. Srivastava R. Naraian S. J. S. Kalra H. Chandra 《International Journal of Environmental Science and Technology》2014,11(6):1787-1800
Irrational and rapid global human societal development has culminated to a condition of environmental deterioration. Accidental leakage and deliberate use of organic and inorganic chemicals have contaminated the environment up to the level of ecosystem. Advancements have been made in the field of research on bioremediation of the hazardous contaminants especially in last three decades. Microbial bioremediation has been the most understood biotechnological process of environmental restoration. Bacteria and fungi because of their inherent ability to adapt and grow in extreme environments have been employed for either removal or degradation of the chemical contaminants. Researchers all over the world are getting breakthroughs in finding new bacterial strains having plasmid linked degradation/reduction ability. Molecular biology and genetic engineering helped in crafting the microbes for the desired results on environment. Despite having favorable conditions, microbial remediation largely depends on environmental factors and on the basic biological characters of microbes, especially bacteria being Gram-positive or Gram-negative. Metagenomic studies revealed the importance of microbial ecology as microbes work well in community, i.e., consortia. This review along with several other studies suggests the need of precision during microbial community identification, substrate specificity and the designing of microbes. 相似文献
15.
土壤/沉积物中石油烃微生物降解研究综述 总被引:3,自引:0,他引:3
结合目前国内外研究进展,综述了土壤和沉积物中石油烃污染物的来源、危害和生物降解的菌种及降解途径,分析了微生物性质和包括氧、营养物、温度、土壤/沉积物理化性质等环境因素对石油烃降解的影响,指出这些研究往往局限于某种特殊污染物、特殊污染降解菌种和单一条件下辅助降解方面,引入了人为因素的影响,造成与实际不符的降解假象。因此,自然条件下石油烃生物降解将成为重要的研究课题。 相似文献
16.
Polycarbonate biodegradation by isolated molds using clear-zone and atomic force microscopic methods
M. Arefian M. Zia A. Tahmourespour M. Bayat 《International Journal of Environmental Science and Technology》2013,10(6):1319-1324
The accumulation of dry waste containing synthetic polymers due to their resistance to microorganisms and other environmental factors has posed some serious problems to the environment in recent years. On the other hand, plastics constitute the foundations of economy as they are widely used in agriculture, constructions, packaging, health care and also medicine. The aim of this research was to investigate the role of different isolated fungi in the degradation of polycarbonate polymers. For this purpose, sampling was done using the garden soil and waste leachate from Isfahan Waste Management Organization. Samples were enriched in the liquid mineral salt medium supplemented with polycarbonate and then were transferred to the same medium solidified with agar to isolate and identify different fungi. Finally, their biodegradation activity was investigated with the help of clear-zone and atomic force microscopic (AFM) techniques, and also lipase and amylase production was tested. Among 15 isolated genera of mold fungi, Fusarium, Ulocladium, Chrysosporium and Penicillium showed biodegradation activity. According to the diameter of clear zone around the fungal colonies and also AFM results, the highest rate of degradation was related to Fusarium. Lipase activity of all isolated fungi was positive, but amylase activity of Ulocladium was negative. It can be concluded that some fungal strains such as Fusarium can be used for the biodegradation of plastic materials as it leads to a very eco-friendly biodegradation process. 相似文献
17.
探讨了对处于受压状态的堆石料进行干湿、冷热变化等环境因素作用下力学性质研究的试验方法。使用新研制的堆石料风化试验仪,对某种泥质粉砂岩堆石料进行了干湿循环、冷热循环以及湿冷-干热耦合变化三种环境条件下的长期变形特性试验研究,探讨了堆石料长期劣化变形的机制。试验结果表明,干湿循环试验和湿冷-干热耦合循环均可导致堆石体产生较大幅度的附加变形,其变形机制包括湿化变形、堆石体颗粒湿胀和干缩循环变形以及堆石料的劣化变形等。环境因素的循环变化可导致堆石体颗粒的劣化,堆石体劣化变形是高土石坝后期变形的重要组成部分。 相似文献
18.
Y. T. Sheu P. J. Lien C. C. Chen Y. M. Chang C. M. Kao 《International Journal of Environmental Science and Technology》2016,13(5):1357-1366
Groundwater at many military factory, munition storage and maneuver sites is contaminated by explosives chemicals that were released into the subsurface. The 2,4,6-trinitrotoluene (TNT) is among the most common explosive pollutants. In this study, two TNT-degrading strains, isolated from TNT-contaminated soils and wastewater sludge, were applied for TNT biodegradation. Based on the 16S rDNA sequence analyses, these two bacterial strains were identified as Achromobacter sp. and Klebsiella sp. via biochemical and DNA analyses. Microcosm study was conducted to evaluate the feasibility and efficiency of TNT biodegradation under aerobic conditions. Results indicate that TNT degradation by-products were detected in microcosms (inoculated with Achromobacter sp. and Klebsiella sp.) with cane molasses addition. Klebsiella sp. and Achromobacter sp. used TNT as the nitrogen source and caused completely removal of TNT. Two possible TNT biodegradation routes could be derived: (1) part of the TNT was transformed to nitrotoluene then transformed to nitrobenzene followed by the nitro substitute process, and trinitrobenzene, dinitrobenzene, and nitrobenzene were detected; and (2) TNT was transformed via the nitro substitute mechanism, and dinitrotoluene followed by nitrotoluene isomers were detected. The initial TNT degradation involved the reduction or removal of the nitro substitute to an amino derivative or free nitrite. Results show that the second route was the dominant TNT biodegradation pathway. The produced by-products were also degraded without significant accumulation during the degradation process. These findings would be helpful in designing a practical system inoculated with isolated TNT degradation strains for the treatment of TNT-contained groundwater. 相似文献